KR100669217B1 - Terminal-to-terminal communication connection control method using ip transfer network - Google Patents

Abstract

The present invention provides a terminal-to-terminal communication connection control method that can be applied to multimedia communication such as communication between IP telephones, voice video communication, and IP multicast communication, and installs a connection server and a relay connection server inside an IP transmission network. The access server is endowed with a function similar to the line connection control of the subscriber switch LS, and the relay access server is endowed with a function similar to the line connection control of the relay switch TS, such as a telephone, an IP terminal, a video terminal, or the like. A terminal connects a line connection control message of a common line signaling method, an initial address message (IAM), an address completion message (ACM), a call passing message (CPG), a response message (ANM) By transmitting and receiving a release message REL and a release completion message RLC, a terminal-to-terminal communication connection control method using an IP transmission network is realized. In addition, by means of setting an address management table in the network node apparatus of the IP transmission network and registering the address of the terminal in the address management table, IP packet communication by multicast with improved information security is realized.

IP packet communication, IP transport network, multicast IP packet communication, terminal to terminal communication access control method

Description

Terminal-to-terminal communication connection control method using IP transmission network {TERMINAL-TO-TERMINAL COMMUNICATION CONNECTION CONTROL METHOD USING IP TRANSFER NETWORK}

1 is a diagram illustrating a method for controlling communication connection between terminals in an IP transport network using a common line signaling method.

2 is a schematic diagram illustrating a configuration of a managed IP network for registering a terminal according to the present invention.

3 is a schematic diagram showing the form of an IP transport network targeted by the present invention.

Fig. 4 is an auxiliary view illustrating the functions of the media router disclosed as the first embodiment of the present invention and the functions of the gateway disclosed as the second embodiment.

Fig. 5 is an explanatory diagram of one form of an IP packet used for explaining the media router and gateway functions of the first and second embodiments of the present invention.

Fig. 6 is a schematic diagram showing the configuration of the media router according to the first embodiment of the present invention and explaining the operation procedure of the media router.

Fig. 7 is a schematic diagram showing the configuration of the media router according to the first embodiment of the present invention and explaining the operation procedure of the media router.

Fig. 8 is a diagram for explaining an address management table inside the network node device of the first embodiment of the present invention.

9 is a diagram for explaining the form of an IP packet appearing in communication between two IP terminals.

10 is a diagram for explaining the form of an IP packet appearing in communication between two IP terminals.

11 is a view for explaining the form of an IP packet appearing in communication between two IP terminals.

It is a figure explaining the form of the IP packet shown in the communication between two IP terminals.

FIG. 13 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication. FIG.

FIG. 14 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication. FIG.

FIG. 15 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication. FIG.

Fig. 16 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication.

FIG. 17 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication. FIG.

FIG. 18 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication. FIG.

Fig. 19 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication.

FIG. 20 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication. FIG.

Fig. 21 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication.

Fig. 22 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication.

Fig. 23 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication.

FIG. 24 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication. FIG.

Fig. 25 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication.

It is a figure explaining the form of the IP packet shown in two IP telephone period communication.

Fig. 27 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication.

Fig. 28 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication.

FIG. 29 is a diagram for explaining the form of an IP packet appearing in two IP telephony communication. FIG.

30 is a diagram illustrating an example of a media router status table in the media router.

Fig. 31 is a block diagram showing the conceptual configuration of a standalone IP telephone.

32 is a block diagram showing the conceptual configuration of a standalone IP audio image device.

FIG. 33 is a diagram for explaining another embodiment of an IP packet shown in two IP telephony communication. FIG.

34 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

FIG. 35 is a diagram for explaining another embodiment of the IP packet shown in two IP telephony communication. FIG.

FIG. 36 is a diagram for explaining another embodiment of the IP packet shown in two IP telephony communication. FIG.

FIG. 37 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication. FIG.

FIG. 38 is a diagram for explaining another embodiment of an IP packet shown in two IP telephony communication. FIG.

Fig. 39 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

40 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication.

FIG. 41 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication. FIG.

FIG. 42 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication. FIG.

Fig. 43 is a view for explaining another embodiment of an IP packet shown in two IP telephone period communication.

FIG. 44 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication. FIG.

45 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

FIG. 46 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication. FIG.

Fig. 47 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

FIG. 48 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication in the first embodiment of the present invention. FIG.

FIG. 49 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication in the first embodiment of the present invention. FIG.

50 is a schematic diagram for explaining RAS management of a media router in the first embodiment of the present invention.

Fig. 51 is a schematic diagram showing the configuration of the gateway of the second embodiment of the present invention and explaining the operation procedure of the gateway.

Fig. 52 is a schematic diagram showing the configuration of the gateway of the second embodiment of the present invention and explaining the operation procedure of the gateway.

Fig. 53 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

Fig. 54 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

Fig. 55 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

56 is a diagram for explaining another embodiment of an IP packet shown in two IP telephony communication in a second embodiment of the present invention.

Fig. 57 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

Fig. 58 is a diagram for explaining another embodiment of the IP packet shown in two IP telephony communication.

Fig. 59 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

FIG. 60 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication. FIG.

Fig. 61 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

Fig. 62 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

Fig. 63 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

64 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication.

FIG. 65 is a diagram for explaining another embodiment of the IP packet shown in two IP telephony communication. FIG.

FIG. 66 is a diagram for explaining another embodiment of an IP packet appearing in two IP telephony communication. FIG.

Fig. 67 is a view for explaining another embodiment of the IP packet shown in the two IP telephone period communication.

Fig. 68 is a diagram for explaining another embodiment of the IP packet shown in the two IP telephony communication.

69 is a view for explaining another address management table in the network node device according to the second embodiment of the present invention.

Fig. 70 is a description example of the gateway status table in the second embodiment of the present invention.

Fig. 71 is a schematic diagram of a media router configuration mounted inside a CATV system in the third embodiment of the present invention.

FIG. 72 is a view for explaining a method for connecting various terminals using the terminal accommodating wireless apparatus and the gateway apparatus in the fourth embodiment of the present invention. FIG.

73 is a block diagram showing a structural example of a gateway in the fifth embodiment of the present invention.

74 is a block diagram showing an example of the configuration when a telephony control server is used in the sixth embodiment of the present invention.

75 is a flowchart for explaining the sixth embodiment of the present invention.

76 is a diagram for explaining a sixth embodiment of the present invention.

77 is a diagram for explaining a sixth embodiment of the present invention.

78 is a flowchart for explaining the sixth embodiment of the present invention.

79 is a diagram for explaining a sixth embodiment of the present invention.

80 is a view for explaining a sixth embodiment of the present invention.

81 is a diagram for explaining a sixth embodiment of the present invention.

82 is a diagram for explaining a sixth embodiment of the present invention.

83 is a diagram for explaining a sixth embodiment of the present invention.

84 is a diagram for explaining a sixth embodiment of the present invention.

85 is a diagram for explaining a sixth embodiment of the present invention.

86 is a flowchart for explaining the sixth embodiment of the present invention.

87 is a view for explaining a sixth embodiment of the present invention.

88 is a diagram for explaining a sixth embodiment of the present invention.

89 is a view for explaining a sixth embodiment of the present invention.

90 is a flowchart for explaining a sixth embodiment (release phase) of the present invention.

91 is a diagram for explaining a sixth embodiment (one telecommunication company) of the present invention.

92 is a flowchart for explaining the sixth embodiment of the present invention.

93 is a flowchart for explaining the sixth embodiment of the present invention.

Fig. 94 is a diagram showing an example of a communication company division table of telephone numbers.

95 is a diagram illustrating an example of a telephone management server classification table of telephone numbers.

96 is a block diagram showing a structural example of a media router as a seventh embodiment of the present invention.

97 is a view for explaining a seventh embodiment of the present invention.

Fig. 98 is a block diagram showing the construction of the eighth embodiment of the present invention.

99 is a flowchart showing the operation example of the eighth embodiment of the present invention.

100 is a view for explaining an eighth embodiment of the present invention.

101 is a diagram for explaining an eighth embodiment of the present invention.

Fig. 102 is a flowchart showing an example of operation of the eighth embodiment of the present invention.

103 is a diagram for explaining an eighth embodiment of the present invention.

104 is a view for explaining an eighth embodiment of the present invention.

105 is a view for explaining an eighth embodiment of the present invention.

106 is a diagram for explaining a sixth embodiment of the present invention.

107 is a diagram for explaining an eighth embodiment of the present invention.

108 is a diagram for explaining the sixth embodiment of the present invention.

109 is a diagram for explaining an eighth embodiment of the present invention.

110 is a view for explaining an eighth embodiment of the present invention.

111 is a diagram for explaining an eighth embodiment (another example of a media router) of the present invention.

112 is a view for explaining an eighth embodiment of the present invention.

113 is a diagram for explaining an eighth embodiment of the present invention.

114 is a diagram for explaining an eighth embodiment of the present invention.

Fig. 115 is a schematic diagram showing a connection state between a part of the inside of the media router and an IP terminal or LAN connected thereto.

116 is a diagram illustrating an example of an originating priority control management table.

117 is a diagram illustrating an example of an originating priority control management table.

118 is a diagram for explaining a ninth embodiment of the present invention.

119 is a block diagram showing the construction of a ninth embodiment of the present invention.

120 is a flowchart showing an operation example of the ninth embodiment of the present invention.

121 is a view for explaining a ninth embodiment of the present invention.

122 is a view for explaining a ninth embodiment of the present invention.

123 is a view for explaining a ninth embodiment of the present invention.

124 is a diagram for explaining a ninth embodiment of the present invention.

125 is a view for explaining a ninth embodiment of the present invention.

126 is a diagram for explaining a ninth embodiment of the present invention.

127 is a diagram for explaining a ninth embodiment of the present invention;

128 is a block diagram showing the construction of a tenth embodiment of the present invention.

129 is a flowchart showing an operation example of the tenth embodiment of the present invention.

130 is a view for explaining a tenth embodiment of the present invention.

131 is a diagram for explaining a tenth embodiment of the present invention.

132 is a diagram for explaining a tenth embodiment of the present invention.

133 is a diagram for explaining a tenth embodiment of the present invention.

134 is a flowchart showing an example of operation of the tenth embodiment of the present invention.

135 is a view for explaining a tenth embodiment of the present invention.

136 is a diagram for explaining a tenth embodiment of the present invention.

137 is a diagram for explaining a tenth embodiment of the present invention.

138 is a diagram for explaining a tenth embodiment of the present invention.

139 is a view for explaining a tenth embodiment of the present invention.

140 is a view for explaining a tenth embodiment of the present invention.

141 is a view for explaining a tenth embodiment of the present invention.

142 is a diagram for explaining a tenth embodiment of the present invention.

143 is a diagram for explaining a tenth embodiment of the present invention.

144 is a view for explaining a tenth embodiment of the present invention.

145 is a diagram for explaining a tenth embodiment of the present invention.

146 is a view for explaining the tenth embodiment of the present invention.

147 is a diagram for explaining a tenth embodiment of the present invention.

148 is a diagram for explaining a tenth embodiment of the present invention.

149 is a view for explaining a tenth embodiment of the present invention.

150 is a view for explaining a tenth embodiment of the present invention.

151 is a diagram for explaining a tenth embodiment of the present invention.

152 is a diagram for explaining a tenth embodiment of the present invention.

153 is a diagram for explaining a tenth embodiment of the present invention.

154 is a diagram for explaining a tenth embodiment of the present invention.

155 is a view for explaining a tenth embodiment of the present invention.

156 is a diagram to describe a tenth embodiment of the present invention.

157 is a diagram for explaining a tenth embodiment of the present invention.

158 is a diagram for explaining a tenth embodiment of the present invention.

159 is a diagram for explaining a tenth embodiment of the present invention.

160 is a view for explaining a tenth embodiment of the present invention.

161 is a view for explaining a tenth embodiment of the present invention.

162 is a flowchart showing an operation example of the tenth embodiment of the present invention.

163 is a flowchart showing an operation example of the tenth embodiment of the present invention.

164 is a flowchart showing the operation example (TCP-IAM) of the tenth embodiment of the present invention.

165 is a flowchart showing the operation example (TCP-ACM) of the tenth embodiment of the present invention.

166 is a flowchart showing the operation example (TCP-CPG) of the tenth embodiment of the present invention.

167 is a flowchart showing the operation example (TCP-ANM) of the tenth embodiment of the present invention.

168 is a flowchart showing the operation example (TCP-REL) of the tenth embodiment of the present invention.

169 is a flowchart showing the operation example (TCP-RLC) of the tenth embodiment of the present invention.

170 is a view for explaining a tenth embodiment of the present invention.

171 is a view for explaining a tenth embodiment of the present invention.

172 is a view for explaining a tenth embodiment of the present invention.

173 is a view for explaining a tenth embodiment of the present invention.

174 is a diagram for explaining a tenth embodiment of the present invention.

175 is a diagram for explaining a tenth embodiment of the present invention.

176 is a diagram for explaining a tenth embodiment of the present invention.

177 is a diagram for explaining a tenth embodiment of the present invention.

178 is a diagram for explaining a tenth embodiment of the present invention.

179 is a diagram for explaining a tenth embodiment of the present invention.

180 is a view for explaining a tenth embodiment of the present invention.

181 is a block diagram showing the construction of the eleventh embodiment of the present invention.

182 is a flowchart showing the operation of the eleventh embodiment of the present invention.

183 is a flowchart showing the operation of the eleventh embodiment of the present invention.

184 is a flowchart showing the operation of the eleventh embodiment of the present invention.

185 is a block diagram showing the construction of a twelfth embodiment of the present invention.

186 is a diagram for explaining a twelfth embodiment of the present invention.

187 is a view for explaining a twelfth embodiment of the present invention;

188 is a flowchart showing the operation of the twelfth embodiment of the present invention.

189 is a flowchart showing the operation of the twelfth embodiment of the present invention.

190 is a flowchart showing the operation of the twelfth embodiment of the present invention.

191 is a flowchart showing the operation of the twelfth embodiment of the present invention.

192 is a flowchart showing the operation of the twelfth embodiment of the present invention.

193 is a diagram for explaining a twelfth embodiment of the present invention.

194 is a flowchart showing the operation of the twelfth embodiment of the present invention.

195 is a diagram for explaining a twelfth embodiment of the present invention.

196 is a diagram for explaining a twelfth embodiment of the present invention.

197 is a block diagram showing a thirteenth embodiment of the present invention.

198 is a flowchart showing the operation example of the thirteenth embodiment of the present invention.

199 is a diagram for explaining a thirteenth embodiment of the present invention.

200 is a view for explaining a thirteenth embodiment of the present invention.

201 is a diagram for explaining a thirteenth embodiment of the present invention.

202 is a diagram for explaining a thirteenth embodiment of the present invention.

203 is a diagram for explaining a thirteenth embodiment of the present invention.

204 is a diagram for explaining a thirteenth embodiment of the present invention.

205 is a view for explaining a thirteenth embodiment of the present invention.

206 is a diagram for explaining a thirteenth embodiment of the present invention.

Fig. 207 is a figure for explaining a thirteenth embodiment of the present invention;

208 is a view for explaining a thirteenth embodiment of the present invention.

209 is a diagram for explaining a thirteenth embodiment of the present invention.

210 is a view for explaining a thirteenth embodiment of the present invention.

211 is a diagram for explaining a thirteenth embodiment of the present invention.

212 is a diagram for explaining a thirteenth embodiment of the present invention.

213 is a diagram for explaining a thirteenth embodiment of the present invention.

214 is a diagram for explaining a thirteenth embodiment of the present invention.

215 is a view for explaining a thirteenth embodiment of the present invention.

216 is a view for explaining a thirteenth embodiment of the present invention.

217 is a view for explaining a thirteenth embodiment of the present invention.

218 is a diagram for explaining a thirteenth embodiment of the present invention.

219 is a diagram for explaining a thirteenth embodiment of the present invention;

220 is a view for explaining a thirteenth embodiment of the present invention.

221 is a view for explaining a thirteenth embodiment of the present invention.

222 is a diagram for explaining a thirteenth embodiment of the present invention.

223 is a diagram for explaining a thirteenth embodiment of the present invention.

224 is a view for explaining a thirteenth embodiment of the present invention.

225 is a diagram for explaining a thirteenth embodiment of the present invention.

226 is a diagram for explaining a thirteenth embodiment of the present invention.

227 is a diagram for explaining a thirteenth embodiment of the present invention.

228 is a diagram for explaining a thirteenth embodiment of the present invention.

229 is a diagram for explaining a thirteenth embodiment of the present invention.

230 is a diagram for explaining a thirteenth embodiment of the present invention.

231 is a view for explaining a thirteenth embodiment of the present invention.

232 is a block diagram showing the fourteenth embodiment of the present invention.

233 is a flowchart showing an operation example of the fourteenth embodiment of the present invention.

234 is a diagram for explaining a fourteenth embodiment of the present invention.

235 is a view for explaining a fourteenth embodiment of the present invention.

236 is a view for explaining a fourteenth embodiment of the present invention.

237 is a diagram for explaining a fourteenth embodiment of the present invention.

238 is a view for explaining a fourteenth embodiment of the present invention.

239 is a view for explaining a fourteenth embodiment of the present invention.

240 is a view for explaining a fourteenth embodiment of the present invention.

241 is a view for explaining a fourteenth embodiment of the present invention.

242 is a diagram for explaining a fourteenth embodiment of the present invention.

243 is a view for explaining a fourteenth embodiment of the present invention.

244 is a view for explaining a fourteenth embodiment of the present invention.

245 is a view for explaining a fourteenth embodiment of the present invention.

246 is a diagram for explaining a fourteenth embodiment of the present invention.

247 is a view for explaining a fourteenth embodiment of the present invention.

248 is a view for explaining a fourteenth embodiment of the present invention.

249 is a view for explaining a fourteenth embodiment of the present invention.

250 is a view for explaining a fourteenth embodiment of the present invention.

251 is a diagram for explaining a fourteenth embodiment of the present invention.

252 is a view for explaining a fourteenth embodiment of the present invention.

253 is a view for explaining a fourteenth embodiment of the present invention.

254 is a diagram for explaining a fourteenth embodiment of the present invention.

255 is a view for explaining a fourteenth embodiment of the present invention.

256 is a flowchart showing the operation example of the fourteenth embodiment of the present invention.

257 is a flowchart showing an operation example of the fourteenth embodiment of the present invention.

258 is a flowchart showing the operation example of the fourteenth embodiment of the present invention.

259 is a flowchart showing an operation example of the fourteenth embodiment of the present invention.

260 is a block diagram showing the fifteenth embodiment of the present invention.

261 is a flowchart showing an operation example of the fifteenth embodiment of the present invention.

262 is a diagram for explaining a fifteenth embodiment of the present invention.

263 is a diagram for explaining a fifteenth embodiment of the present invention.

264 is a diagram for explaining a fifteenth embodiment of the present invention.

265 is a diagram for explaining a fifteenth embodiment of the present invention.

266 is a diagram for explaining a fifteenth embodiment of the present invention.

267 is a diagram for explaining a fifteenth embodiment of the present invention.

268 is a diagram for explaining a fifteenth embodiment of the present invention.

269 is a diagram for explaining a fifteenth embodiment of the present invention.

270 is a diagram for explaining a fifteenth embodiment of the present invention.

271 is a diagram for explaining a fifteenth embodiment of the present invention.

272 is a view for explaining a fifteenth embodiment of the present invention.

273 is a diagram for explaining a fifteenth embodiment of the present invention.

274 is a diagram for explaining a fifteenth embodiment of the present invention.

275 is a view for explaining a fifteenth embodiment of the present invention.

276 is a view for explaining a fifteenth embodiment of the present invention.

277 is a diagram for explaining a fifteenth embodiment of the present invention.

278 is a diagram for explaining a fifteenth embodiment of the present invention.

279 is a diagram for explaining a fifteenth embodiment of the present invention.

280 is a diagram for explaining a fifteenth embodiment of the present invention.

Fig. 281 is a figure for explaining a fifteenth embodiment of the present invention.

282 is a diagram for explaining a fifteenth embodiment of the present invention.

283 is a diagram for explaining a fifteenth embodiment of the present invention.

284 is a diagram for explaining a fifteenth embodiment of the present invention.

285 is a diagram for explaining a fifteenth embodiment of the present invention.

286 is a diagram for explaining a fifteenth embodiment of the present invention.

287 is a diagram for explaining a fifteenth embodiment of the present invention.

288 is a block diagram showing a sixteenth embodiment of the present invention.

289 is a flowchart showing an operation example of the sixteenth embodiment of the present invention.

290 is a view for explaining a sixteenth embodiment of the present invention.

291 is a view for explaining a sixteenth embodiment of the present invention.

292 is a diagram for explaining a sixteenth embodiment of the present invention.

Fig. 293 is a part of a block diagram showing the construction of the seventeenth embodiment of the present invention.

Fig. 294 is a part of a block diagram showing the construction of the seventeenth embodiment of the present invention.

Fig. 295 is a part of a block diagram showing the construction of the seventeenth embodiment of the present invention.

296 is a diagram for explaining a seventeenth embodiment of the present invention.

297 is a diagram for explaining a seventeenth embodiment of the present invention.

298 is a view for explaining the seventeenth embodiment of the present invention.

299 is a view for explaining the seventeenth embodiment of the present invention.

300 is a flowchart for explaining the operation of the seventeenth embodiment of the present invention.

301 is a diagram for explaining a seventeenth embodiment of the present invention.

302 is a diagram for explaining a seventeenth embodiment of the present invention.

303 is a diagram for explaining a seventeenth embodiment of the present invention.

304 is a diagram for explaining a seventeenth embodiment of the present invention.

305 is a view for explaining the seventeenth embodiment of the present invention.

306 is a diagram for explaining a seventeenth embodiment of the present invention.

307 is a view for explaining the seventeenth embodiment of the present invention.

308 is a view for explaining a seventeenth embodiment of the present invention.

309 is a part of figure for explaining the address management table in the seventeenth embodiment of the present invention.

Fig. 310 is a part of the figure for explaining the address management table in the seventeenth embodiment of the present invention.

Fig. 311 is a part of the figure for explaining the address management table in the seventeenth embodiment of the present invention.

312 is a diagram for explaining a seventeenth embodiment of the present invention.

313 is a diagram for explaining a seventeenth embodiment of the present invention.

314 is a diagram for explaining a seventeenth embodiment of the present invention.

315 is a view for explaining the seventeenth embodiment of the present invention.

316 is a view for explaining the seventeenth embodiment of the present invention.

317 is a view for explaining the seventeenth embodiment of the present invention.

318 is a diagram for explaining a seventeenth embodiment of the present invention.

319 is a view for explaining the seventeenth embodiment of the present invention.

320 is a view for explaining a seventeenth embodiment of the present invention.

321 is a part of block diagram showing the construction of the eighteenth embodiment of the present invention.

322 is a part of block diagram showing the construction of the eighteenth embodiment of the present invention.

323 is a part of block diagram showing the construction of the eighteenth embodiment of the present invention.

324 is a part of block diagram showing the construction of the eighteenth embodiment of the present invention.

325 is a flowchart for explaining the operation of the eighteenth embodiment of the present invention.

326 is a flowchart for explaining the operation of the eighteenth embodiment of the present invention.

327 is a diagram for explaining an eighteenth embodiment of the present invention.

328 is a view for explaining an eighteenth embodiment of the present invention.

329 is a diagram for explaining an eighteenth embodiment of the present invention.

330 is a part of block diagram showing the construction of the nineteenth embodiment of the present invention.

331 is a part of block diagram which shows a structure of 19th Embodiment of this invention.

332 is a part of block diagram showing the construction of the nineteenth embodiment of the present invention.

333 is a view for explaining a nineteenth embodiment of the present invention.

334 is a diagram for explaining a nineteenth embodiment of the present invention.

335 is a block diagram showing a construction of a twentieth embodiment of the present invention.

336 is a flowchart for explaining the operation of the twentieth embodiment of the present invention.

337 is a diagram for explaining a twentieth embodiment of the present invention.

338 is a diagram for explaining a twentieth embodiment of the present invention.

339 is a block diagram schematically illustrating an integrated IP transport network.

340 is a block diagram for explaining a relationship between an exchange and a signal network.

341 is No. It is a figure which shows an example of the signal unit of 7-common line signal system.

342 is a flowchart for explaining a relationship between an exchange and a signaling network.

343 is a flowchart for explaining a relationship between an exchange and a signaling network.

344 is a flowchart for explaining a relationship between an exchange and a signaling network.

345 is a flowchart for explaining a relationship between an exchange and a signaling network.

346 is a block diagram illustrating basic functions of a gateway.

347 shows an example of call control data in an IP packet.

348 shows an example of voice data in an IP packet.

349 shows an example of video data in an IP packet.

350 is a block diagram illustrating a basic principle of an integrated information communication network.

351 is a block diagram illustrating a basic principle of an integrated information communication network.

352 is a block diagram illustrating a basic principle of an integrated information communication network.

353 is a view for explaining the operation of the integrated information communication network.

354 is a block diagram illustrating a configuration example of a multicast IP transport network.

355 shows an example of a multicast table used in a multicast IP transport network.

356 is a diagram for explaining the present invention.

357 is a view for explaining the present invention;

358 is a diagram for explaining the present invention.

359 is a diagram for explaining the present invention.

360 is a diagram for explaining the present invention.

<Explanation of symbols for main parts of drawing>

1: IP transmission network

1-1, 1-2: Terminal

1-3, 1-4 ： Media Router

1-5, 1-6 ： Connection Server

1-7 ： Relay connection server

1-10 ： IP Transport Network

1-11, 1-12, 1-13, 1-14: Network node device

1-15 to 1-20: Router

2: Integrated IP transport network

3: IP data network

4: IP telephone network

5-1: IP audio system

5-2: Best effort network

6-1 ： Scope of IP transport network managed and operated by communication company X

6-2: Range of IP transmission network managed by telecommunication company Y

7-1, 7-2, 7-3, 7-4: Network node device managed by telecommunication company X

8-1, 8-2, 8-3, 8-4: Network node device managed by telecommunication company Y

9-1, 9-2 ： Gateway

10-1 to 10-8: External communication network of integrated IP transport network 1

11-1 to 11-10: IP terminal

12-1, 12-2 ： Standalone IP Phone

12-3: Standalone IP audio system

13-1, 13-2, 13-3, 13-4 ： Non-Independent IP Phone

14-1, 14-2, 14-3, 14-4 ： Media Router

15-1, 15-2 ： LAN

16-1, 16-2, 16-3, 16-4: Non-Independent IP Voice Imaging Device

17-1, 17-2, 17-3, 17-4: Public telephone line

18-1-18-8: Analog phone

19-1 to 19-19: Router with IP forwarding function

20-1 to 20-4: Routers used in the LAN or inside the media router

21-1 to 21-5: Routers used between different IP transmission networks of telecommunication companies

22-1, 22-2: Connection control unit

23-1, 23-2: H323 terminal part

24-1, 24-2: SCN boundary

27-1, 27-2 ： ATM network

27-3 ： Optical communication network

27-4 ： Frame relay switching network

30-1 to 30-4: Dedicated domain name server of IP data network

31-1, 31-2: Dedicated domain name server of IP telephone network

32-1, 32-2: Dedicated domain name server of IP audio visual network

33-1, 33-2: Dedicated domain name server of the best effort network

35-1, 35-2: IP data service operation management server (DSS)

36-1, 36-2: IP telephone service operation management server (TES)

37-1, 37-2: IP audio visual service operation management server (AVS)

38-1, 38-2: Best effort service operation management server (BES)

48-1, 78-1: Domain name server

The present invention provides a terminal-to-terminal communication connection using an IP transmission network applicable to IP communication between two terminals, such as an IP (Internet Protocol) terminal, an IP telephone, and an audio image device, or a 1: n IP communication using a multicast IP technology. It relates to a control method.

Japanese Patent Application No. Hei 11-128956 (hereinafter referred to as "prior application") by the present applicant is a method for realizing communication between various terminals such as mail transmission and reception, telephone and video communication using an IP transmission network. The application discloses a method for realizing an "integrated IP transport network" comprising a plurality of IP transport networks having various characteristics such as an IP telephone network, an IP video network, and an IP electronic data general purpose network. In order to realize an IP transmission network in which various terminal communications are integrated, the contents disclosed by the foregoing application will be schematically described with reference to FIG. 339.

Inside the integrated IP transport network 901, a plurality of IP transport networks having different characteristics such as an IP video network 902, an IP electronic data general purpose network 903, and an IP telephone network 904 are virtually installed, and an integrated IP transport network ( An address management table is set in each of the network node apparatus 905-X or 905-Y provided at an input point from the outside of the 901 to the integrated IP transport network 901, and the address and the like of the terminal are previously set in this address management table. By registering and comparing the address written in the IP packet input to the integrated IP transport network 901 with the address registered in the address management table, the individual IP transport network in the integrated IP transport network 901 is compared. It distributes to and transmits.

Next, the present invention relates to a terminal-to-terminal communication connection control method (No. 7 common line signaling method) employed in a public switched telephone network (PSTN).

In Fig. 340, reference numerals 98-1 and 98-3 denote switchboards (subscriber exchangers) to which telephones are connected, 98-2 denote relay exchanges, and 98-4 and 98-5 telephones. 98-6 to 98-8 are the call control units of the exchange, 98-9 to 98-11 are the internal control units of the exchange, and 98-12 to 98-14 are signal stations (SP: Signaling Point) for controlling the connection between the terminals of the telephone. to be. The switch internal control unit controls the internal operation of the switch and exchanges information for setting or restoring a call line between the call path control unit and the signal station.

In particular, 98-12 and 98-14 are called signal end stations (SEP), and in particular, 98-13 are called signal relay stations (STP). 98-15 is another signal station. These signal stations 98-12 to 98-15 are connected to the signal network 98-16 via signal lines 98-24 to 98-27, respectively, and signal information used for communication connection control between terminals and maintenance and operation of the network. They are stored in a signaling unit (SU) and communicate with each other between signal stations. The signal station is provided with a 16-bit signal station code (PC: Point Code) for identification with other signal stations. On the other hand, 98-21 and 98-22 are telephone lines for transmitting telephone voice, and do not transmit information for communication connection control between terminals. Telephone lines 98-20 and 98-23 are interfaces in which voice and terminal-to-terminal communication connection control information are integrated, that is, voice and terminal-to-terminal communication connection control information are transmitted without being separated (referred to as UNI). Signal lines 98-24 to 98-26 and call lines 98-21 and 98-22 are separated from inside a public switched telephone network (PSTN). It is characteristic of 7-common line signal system.

The signal unit shown in Fig. 341 includes a "destination signal station code" (DPC: Destination Point Code), an "originating signal station code" (OP: Origin Point Code), a "line number" (CIC: Circuit Identification Code), and a message. It contains the type (MSG: message) and the message parameters.

The destination signal station code indicates the destination to which the signal unit is to be sent, the origin signal station code indicates the source of the signal unit, and the circuit number (CIC: Circuit Identification Code) indicates the call line set between the source signal station and the destination signal station. Identifier number identifying For each message type, for example, there are IAM, ACM, CPG, ANM, REL, RLC, SUS, RES, and CON for use in communication connection control between terminals. A signal unit written in IAM in the message type area of the signal unit is called an initial address message (IAM). Similarly, the signal unit written in ACM in the message type area of the signal unit is an address completion message (ACM), the signal unit written in CPG is a call passing message (CPG), the signal unit written in ANM is a response message (ANM), A signal unit written in REL is a release message (REL), a RLC signal unit is a release completion message (RLC), a SUS signal unit is a stop message (SUS), and a RES signal unit is written a resume message ( The signal units written in RES and CON are called connection messages SUS.

342 illustrates a method for controlling terminal-to-terminal communication connection for telephone communication with telephone 98-5 via telephone exchange 98-1, 98-2 and 98-3 from telephone 98-4 shown in FIG. It demonstrates with reference to. In addition, each signal station sets a signal unit in which signal station codes assigned to these signal stations are set as addresses indicating a destination and a transmission source, and the signal lines 98-24 to 98-27 and the common line signal network 98-. Replace via 16). The telephone 98-4 and the switch 98-1 are connected by a telephone line 98-20, and the terminal-to-terminal connection control of the telephone set 98-4 is the signal station 98- in the switch 98-1. 12) is in charge. Similarly, telephone 98-5 and switch 98-3 are connected by telephone line 98-23, and the terminal-to-terminal connection control of phone 98-5 is connected to the signal station in switch 98-3. 98-14).

When the user requests a call origination from the telephone 98-4, the signal station 98-12 receives (step X1 in FIG. 342), and the call path control section 98-6 and the switch interior of the switch 98-1 are received. By the function of the control unit 98-9, a communication line is determined using the destination telephone number received from the telephone 98-4, and the signal unit in which the communication line identifier (CIC) is written is an initial address message. It is formed as (IAM). At least the telephone number of the telephone 98-5, that is, the destination telephone number " Tel-No-98-5 " is entered in the parameter area of the initial address message IAM. It is also possible to enter the telephone number of the telephone 98-4, that is, the source telephone number "Tel-No-98-4".

The signal station 98-12 then sends an initial address message IAM for making a telephone call to the signal station 98-13 in the switch 98-2 (step X2). IAM includes line number "98-4-98-5", destination telephone number "TeI-No-98-5", and source telephone number "Tel-" of a call line, which is a logical communication line inside call line 98-21. No-98-4 "(optional option) is included. After transmitting the IAM, the signal station 98-12 transitions to the standby state of the address completion message (ACM) described later, and starts the ACM wait timer.

The signal station 98-13 in the switch 98-2 receives the IAM and passes the switch number 989898-5 to the call line controller 98-7 via the switch internal controller 98-10. &Quot;, the call line control section 98-7 performs a conduction test to make the call line 98-21 callable, and the signal station 98-13 makes the signal station 98 in the switch 98-3 available. (14), the signal station 98-14 examines the contents of the received IAM and passes the control line 98-11 and the call line control unit 98-8 to the call line 98; -22), and the signal station 98-14 connects the telephone 98-5 to the switch 98-3 to check whether the incoming call is allowed. A call setup request is made to the telephone set 98-5 (step X4), and the signal station 98-14 returns an address completion message (ACM) notifying that the IAM has been received (step X5), and the ACM signals Reach signal station 98-12 past station 98-13 (Step X6). When the signal station 98-12 receives the ACM, it stops the ACM waiting timer already set. In addition, when the ACM waiting timer expires before the ACM is received, the call line is released.

When signal station 98-14 in exchange 98-3 receives information indicating that it is ringing a ringing tone from telephone 98-5 (step X7), a call passing message is sent to signal station 98-13. (CPG) is transmitted (step X8), the signal station 98-13 transmits the received CPG to the signal station 98-12 (step X9), and the signal station 98- in the switch 98-1. 12 receives the CPG, and then the signal station 98-12 transmits a ring tone to the telephone 99-4 (step X10). When the telephone 98-5 responds to the call setup request (step X11), the telephone line 98-23 between the telephone 98-5 and the switch 98-4 is made available for communication, and the telephone ( A response message (ANM) indicating that 98-5) has responded is sent to the signal station 98-13 (step X12).

The signal station 98-13 transmits the received ANM to the signal station 98-12 (step X13), and the signal station 98-12 notifies stop of the ring tone being transmitted to the telephone 98-4. (Step X14), the telephone voice can be transmitted and received between the telephone set 98-4 and the telephone set 98-5, and the process shifts to the call phase (step X15). When the handset of the telephone 98-4 is placed (on-hook), the release request REL is sent (step X16), and the signal station 98-12 receives the release request REL, then releases the next release. A request REL is sent to the signal station 98-13 (step X17), and the telephone 98-4 is notified of the completion of release (RLC) indicating that the call line is in an empty (callable) state. (Step X18). When the signal station 98-13 receives the release request REL, the signal station 98-13 sends the next release request REL to the signal station 98-14 (step X19), and the call line is empty (callable). The signal station 98-12 is notified to the signal station 98-12 indicating that the state has been released (step X20), and when the signal station 98-14 receives the release request REL, the next release request REL is received. It transmits to telephone 98-5 (step X21), and notifies signal station 98-13 of release completion (RLC) indicating that the call line is empty (step X22). The order of the terminal-to-terminal communication connection control transmitted and received between the phone 98-4 and the signal station 98-12, and between the signal station 98-14 and the phone 98-5 varies depending on the type of the phone. For example, immediately after step X18, a confirmation notification of the completion of release from the phone 98-4 is signaled to the signal station 98-12, or from the signal station 98-14 immediately after step X23. -5) may be sent a confirmation notice to complete the release.

Fig. 343 is a view for explaining another terminal-to-terminal communication connection control method for making telephone communication with the telephone set 98-5 from the telephone set 98-4 via the switching units 98-1 to 98-3. This terminal-to-terminal communication connection control method corresponds to that excepting step X5 and X6, that is, address address completion message ACM, in the terminal-to-terminal communication connection control method described in FIG. 296. However, in step X2, the signal station 98-12 sets the CPG waiting timer instead of the ACM waiting timer, and the signal station 98-12 stops the CPG waiting timer after step X9. The above-described terminal-to-terminal communication connection control method employs an exchange as an analog exchange instead of an ISDN exchange.

Fig. 344 is a view for explaining another terminal-to-terminal communication connection control method between the telephone set 98-4 and the telephone set 98-5. In this terminal-to-terminal communication connection control method, in the aforementioned terminal-to-terminal communication connection control method, This is an example of performing a series of steps for interrupting telephone communication without waiting for a response completion message (step X14) and a call phase (step X15) (steps X16 to X23).

345 is yet another terminal-to-terminal communication connection control method for telephone communication from telephone 98-4 to telephone 98-5 via switchboards 98-1 to 98-3, and during a call (step X15). The handset of the telephone 98-4 is placed only for a short time (on-hook), and an interruption message for temporarily stopping telephone communication is sent (steps X30 to X33), and the handset returns (off-hook). A resume message in which telephone communication is resumed is transmitted (steps X35 to X38), and the case of returning to a call (step X39) is shown. Subsequent release REL and release complete RLC steps are the same as those described with reference to FIG. 343 (steps X40 to X47).

Next, regarding IP telephony, there is a TTC standard "Multimedia communication system based on JT-H323 packet", for example, described in ITU-T recommendation H323 ANNEX D standard (April 1999 edition). The "signalling protocol and packetization of media signals" technique for controlling the call connection in the communication between multimedia terminals is defined as JT-H225, and the "control protocol for multimedia communication" in the communication between multimedia terminals is It is prescribed as JT-H245.

Next, the basic functions of the JT-H323 gateway referred to in the present invention and defined by the ITU will be described with reference to FIGS. 346 to 349.

In FIG. 346, block 800 is a JT-H323 gateway, and an audio or video signal input from the SCN line 801 is converted into a digital data signal in the SCN terminal function block 802, and the data format is converted in the conversion function block 803. Signal transmission / reception rules and the like are converted, and are converted in the form of an IP packet by the terminal function block 804 and transmitted to the IP communication line 805. The reverse direction flow, that is, an IP packet including voice or image data input from the IP communication line 805 is decoded in the form of digital data in the terminal function block 804, and the conversion function block 803 The data format, the signal transmission / reception rule, and the like are converted, and the SCN terminal function block 802 is converted into a signal flowing through the SCN line and transmitted to the SCN line 801. Here, the voice or image signal can be divided into "call control data" used for exchanging telephone numbers with a communication partner and the like, and "net data" constituting the voice or image itself. The communication line 805 has an IP packet 810 (Fig. 347) as call control data, an IP packet 811 (Fig. 348) as net data constituting voice, and an IP packet 812 (Fig. 349) as net data constituting the image itself. ) Is delivered. For ISDN lines, SCN terminal function block 802 corresponds to a data line termination unit (DSU). In addition, the terminal function block 804 has a terminal communication function required for two-way communication with a JT-323 telephone or a JT-323 audio visual apparatus. In block 346, block 800 is a JT-H323 gateway and an SCN line. The voice or image signal input from the 801 is converted into a digital data signal by the SCN terminal function unit 802, the data format, the signal transmission / reception rule, etc. are converted by the conversion function unit 803, and the terminal function unit 804 Is converted into the form of an IP packet and sent out to the IP communication line 805. The reverse direction flow, that is, an IP packet including voice or image data input from the IP communication line 805 is decoded in the form of digital data by the terminal function unit 804, and the conversion function unit 803 A data format, a signal transmission / reception rule, and the like are converted, and the SCN terminal function unit 802 converts the signal into a signal flowing through the SCN line and sends it to the SCN line 801. Here, the voice or image signal can be divided into "call control data" used for exchanging telephone numbers with a communication partner and the like, and "net data" constituting the voice or image itself. The communication line 805 includes an IP packet 810 (Fig. 347) as call control data, an IP packet 811 (Fig. 348) as net data constituting voice, and an IP packet as net data constituting the image itself ( 812 (FIG. 349) flows. In the case of an ISDN line, the SCN terminal function unit 802 corresponds to a data line termination unit (DSU). In addition, the terminal function unit 804 has a terminal communication function necessary for bidirectional communication with a JT-323 telephone or a JT-323 audio visual apparatus.

Next, the integrated information communication network of Japanese Patent No. 3084681 closely related to the present invention will be schematically described with reference to FIG.

Block 191 is an integrated IP network, IP terminal 192-1 has an IP address "EA01", and IP terminal 192-2 has an IP address "EA02". This example is an example of transmitting the external IP packet 193-1 from the IP terminal 192-1 to the IP terminal 192-2 via the integrated IP communication network, and the IP addresses " EA01 " and " EA02 " Since it is used outside the IP communication network 191, it is called an external IP address. 350 to 353, the header portion of the IP describes only the IP address portion, and other items are omitted.

When the network node device 195-1 receives the external IP packet 193-1, the network node device 195-1 is provided to an end portion (logical terminal) of the logical communication line 194-1 inputted by the IP packet 193-1. Confirm that the internal IP address is " IA01 " and the destination external IP address of the IP packet 193-1 is " EA02 ". Then, the inside of the address management table 196-1 shown in FIG. Search for a record in which the internal IP address is " IA01 " and then " EA02 " as the destination external IP address, and " EA01 " as the source external IP address in the IP packet 193-1 in the detected record. To see if it is included. It is also possible to omit whether or not "EA01" is included as a source external IP address in the IP packet 193-1 in the detected record.

In this example, it is the record including "EA01, EA02, IA01, IA02" in the second row from the top, and the source IP address is "IA01" using the number "IA0I" and "IA02" of the IP address inside the record. An IP packet 193-2 having an IP header whose new IP address is " IA02 " is formed (encapsulation of the IP packet). Here, "IA0I" and "IA02" are referred to as internal IP addresses of the integrated IP communication network 191. The internal IP packet 193-2 arrives at the network node device 195-2 via routers 197-1, 197-2, and 197-3. The network node device 195-2 excludes the IP header of the received internal IP packet 193-2 (decapsulation of the IP packet), and transfers the obtained external IP packet 193-3 to the communication line 194-2. IP terminal 192-2 receives the external IP packet 193-3. Reference numeral 197-6 denotes an example of a server having an external IP address of "EA8I" and an internal IP address of "IA81".

351 is another embodiment of the address management table. The address management table 196-1 of FIG. 350 is replaced with the address management table 196-3 of FIG. 351, and the address management table 196-2 of FIG. 350 is replaced with the address of FIG. Changed to management table 196-4, the other parts are the same. The address management tables 196-3 and 196-4 may apply known address mask techniques.

Initially, the record of the address management table 196-3 including the internal IP address " IA01 " assigned to the logical terminal of the terminal of the communication line 194-1 is retrieved. In this case, the address management table 196-3 is retrieved. The first row of records and the second row of records correspond to the above, and the records of the first row correspond to the external IP mask "Mask81" for the destination and the destination external IP address "EA02" in the external IP packet 193-1. It checks whether the result of the "and" operation matches the destination external IP address "EA81x" in the first row record (Equation (1) below), but in this case, the external IP for the destination is not matched for the next row of records. In order to check whether the "and" operation result of the mask "Mask2" and the destination external IP address "EA02" in the external IP packet 193-1 matches the destination external IP address "EA02y" in the first row record (the following equation ( 2)), in this case. The sender IP address is also compared by the following equation (3) as described above.

If ("Mask81" and "EA02" = "EA81x"). (One)

If ("Mask2" and "EA02" = "EA02y")... (2)

If ("Mask1y" and "EA01" = "EA01y")... (3)

According to the result of the comparison, the second row of records is selected, and the inner records " IA01 " and " IA02 " in the second row of records are used to encapsulate to form an inner IP packet 193-2.

352 is still another embodiment of the address management table. The address management table 196-1 of FIG. 350 is replaced with the address management table 196-5 of FIG. 352, and the address management table 196-2 of FIG. 350 is replaced with that of FIG. Changed to the address management table 196-6, the other parts are the same. In this example, the source external IP address in the address management tables 196-5 and 196-6 is designated as "don't care", and the source external IP address is not cited in the IP encapsulation. When encapsulating the IP packet 193-1, the destination internal IP address "IA02" is determined from the source internal IP address "IA01" and the destination external IP address "EA02" in the address management table 196-5. In this embodiment, since the external source IP address of the address management table is not used, the address management table can be implemented so as not to include the area for the external source IP address.

FIG. 353 is yet another embodiment of the address management table, which corresponds to replacing the integrated IP communication network of FIG. 350 with an optical network and replacing an internal IP packet with an internal optical frame, and will be described below schematically. Block 191x is an IP packet transmission network and is also an optical network for transmitting IP packets by optical frames. The optical frame is transmitted in the optical communication path, which is a function of the first floor to the second floor of communication within the optical network 191x. The optical link address is given to the header portion of the optical frame. In the case where the optical frame is an HDLC frame, the optical link address becomes the HDLC address used in the HDLC frame.

IP terminal 192-1x has IP address "EA1" and IP terminal 192-2x has IP address "EA2". This example is an example of transmitting an external IP packet 193-1x from the IP terminal 192-1x to the IP terminal 192-2x via the optical network 191x. In FIG. 353, the header portion of the IP describes only the IP address portion, and the optical frame also describes only the header portion and omits other items.

When the network node device 195-1x receives the external IP packet 193-1x, the network node device 195-1x is provided to an end portion (logical terminal) of the logical communication line 194-1x to which the IP packet 193-1x is input. Confirm that the internal optical link address is " IA1 " and the destination external IP address of the IP packet 193-1x is " EA2 ", and then search inside the address management table 196-1x shown in FIG. Search for a record in which the source internal optical link address is " IA1 " and then the destination external IP address is " EA2 ", and " EA1 as the source external IP address in the IP packet 193-1x in the detected record. "To see if it is included. It is also possible to omit whether or not "EA1" is included as a source external IP address in the IP packet 193-1x in the detected record.

In this example, the record includes "EA1, EA2, IA1, IA2" in the second row from the top, and the source optical link address is "IA1" using "IA1" and "IA2" of the optical link address in the record. And form an optical frame 193-2x having a header whose destination optical link address is " IA2 " (encapsulation of an IP packet). Here, addresses "IA1" and "IA2" are internal addresses of the optical communication network 191x. The internal optical frame 193-2x arrives at the network node device 195-2x via routers 197-1x, 197-2x, and 197-3x having the optical frame transmission function. The network node device 195-2x removes the header of the received internal optical frame 193-2x (decapsulation of the optical frame) and transfers the obtained external IP packet 193-3x to the communication line 194-2x. The IP terminal 192-2x receives the external IP packet 193-3x.

In the present invention, IP telephones, media routers described below, and various servers (collectively referred to as "IP transmit / receive nodes") are assigned IP addresses, and IP packets can be transmitted and received to exchange data with each other. In the present invention, it is called "IP communication means". 353 shows that the IP transmit / receive node 340-1 and the IP transmit / receive node 340-2 have IP addresses " AD1 " and " AD2 ", respectively, from the terminal 340-1 to the terminal 340-2. This is an example in which various types of data are transmitted / received by transmitting an IP packet 341-1 with a source IP address "AD1" and a destination IP address "AD2" and receiving the IP packet 341-2 in the reverse direction. The data portion excluding the header of the IP packet is also called a payload.

Next, the IP data multicast network, which transmits IP data such as an electronic book or an electronic newspaper, from one delivery source to a plurality of destinations using a multicast technology, which is one of the IP technologies, is used as an IP transmission network. IP-based TV broadcasting networks and IP-based movie distribution networks as IP voice video networks for transmitting (broadcasting) image data to a plurality of destinations, and multicast transmitting from one delivery source to a plurality of destinations with reference to FIG. The type IP transmission network 27-1 will be described.

In FIG. 354, reference numerals 27-11 to 27-20 are routers, and each router has a multicast table for each router indicating that IP packets are transmitted to a plurality of communication lines for each multicast address included in the received IP packet. have. In the present embodiment, the multicast address specifies "MA1". When the IP packet 29-1 having the multicast address " MA1 " is transmitted from the IP terminal 28-1, and arrives at the router 27-18 via the router 27-11, the router 27-18. ) Copies the IP packet 29-2, quotes the router-specific multicast table held by the router 27-18, and transmits the IP packets 29-3 and 29-4 to the communication line. The router 27-17 copies the received IP packet 29-3, refers to the router-specific multicast table, converts the IP packet 29-5 to the communication line 29-17, and the IP packet 29 -6) to the communication line 29-18. Since the router 27-19 does not have a router-specific multicast table, the IP packet 29-4 passes through the router 27-19 as it is, and becomes an IP packet 29-7 to the router 27-14. Is sent.

The router 27-17 inputs the IP packet 29-3 from the communication line 29-16 as shown in Fig. 355, and the source IP address of the IP packet 29-3 is " SRC1 " Confirm that the new IP address is the multicast address "MA1", and the output interfaces are designated as "IF-1" and "IF-2" for the multicast address "MA1" in the multicast table 29-15. As a result, the router 27-17 copies the IP packet 29-3 and outputs it as an IP packet 29-5 to the communication line 29-17 having the output interface " IF-1 " 27-17 copies the IP packet 29-3 and outputs it as the IP packet 29-6 to the communication line 29-18 whose output interface is "IF-2".

The router 27-12 copies the received IP packet 29-5, refers to the multicast table for each router, and sends the IP packet 29-8 to the IP terminal 28-2, and the IP packet 29-9. ) Is transmitted to the IP terminal 28-3, respectively. The router 27-13 copies the received IP packet 29-6 and sends the IP packet 29-10 to the IP terminal 28-4 by referring to the multicast table for each router, and the IP packet 29-11. ) Is transmitted to the IP terminals 28-5, respectively. The router 27-14 copies the received IP packet 29-7, refers to the multicast table for each router, and sends the IP packet 29-12 to the IP terminal 28-6, and the IP packet 29-13. ) Is transmitted to the IP terminals 28-7, respectively. When the IP terminal 28-1 of the sender transmits an electronic book or electronic newspaper in digital data format to the IP transmission network 27-1, the IP transmission network 27-1 is used to deliver the electronic book or electronic newspaper. An IP data multicast network, and IP terminals 28-2 to 28-8 become IP terminals of users who subscribe to electronic books or electronic newspapers. If the IP terminal 28-1 of the sender is broadcasted on behalf of an audio image transmitting apparatus for TV broadcasting, and the TV program (audio and image) is broadcast, the IP transmission network becomes an IP based TV broadcasting network, and the IP terminal 28-2. 28-7) become an IP terminal having a TV receiving function for a TV viewer.

In the multicast embodiment of FIG. 354 described above, the IP terminal 28-1 is a sender and transmits multicast data, and the IP terminals 28-2 to 28-7 are receivers. Adopted multicast is being used for the test on the Internet, wide area LAN, and the like. However, in this multicast scheme, since any IP terminal can be a source of multicast data, there is a risk that a malicious sender appears and continues to send an unlimited number of multicast data, thereby congesting the network and shutting down the network function. In addition, rewriting the multicast table inside the router or sending an unlimited amount of data to the router may overload the router and risk down. It is expected to realize a multicast scheme that improves information safety by limiting the multicast data transmission sources to eliminate illegal actors or to prevent attacks such as overloading down routers.

An inter-terminal communication connection control method between IP terminals mainly transmitting and receiving data has been established as an inter-terminal communication connection control method for transmitting and receiving electronic mail, for example, on the Internet. The present invention provides a method for controlling the terminal-to-terminal communication connection between IP terminals primarily intended for data transmission and reception established in the Internet, and the like. It is to establish a communication connection control method between terminals that can be applied to multimedia communication.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a terminal-to-terminal communication connection control method that can be applied to multimedia communication such as communication between IP telephones, voice video communication, and IP multicast communication. It is.

In the present invention, No. By rethinking the line connection control method of the No. 7-common line signal system to the IP transmission network, the IP transmission network between terminals such as telephones, IP terminals, voice moving picture transmission / reception terminals, and fax terminals is passed. A communication connection control method between terminals is realized.

Referring to reference numeral 1 in Fig. 1, IP transmission networks 1-1 and 1-2 having IP packet transmission / reception functions are terminals (telephones, IP terminals, faxes of voice moving image transmission / reception terminals, etc.), reference numerals 1-3 and 1-4. Is a media router for connecting one or more terminals to an IP transport network, reference numerals 1-5 and 1-6 denote access servers, and reference numerals 1-7 denote relay access servers. Each of the access servers 1-5 and 1-6 is provided with a function similar to the line connection control of the subscriber switch LS of the public switched telephone network (PSTN), and the relay access server 1-7 has a line of the relay switch (TS). Functions similar to connection control are provided.

The user inputs the destination telephone number from the terminal 1-1 to send the call setup (step Z1), and the media router 1-3 returns the call setup acceptance (step Z2), and then the media router 1 -3) transmits an IP packet for call setup including the destination telephone number and the source telephone number to the access server 1-5 (step Y1), and the access server 1-5 receives the received destination phone. A communication line for inter-terminal communication in the IP transmission network is determined using the number, and an IP packet including a line number (CIC) for identifying a communication line, a destination telephone number, and a source telephone number is formed. Here, the line number (CIC) is determined collectively so that the group of the destination telephone number and the source telephone number can be identified. This IP packet is called an IP packet containing an initial address message (IAM) or simply an initial address message (IAM). The communication line for inter-terminal communication is, for example, an IP communication line for transmitting digitized voice packets, and the IP communication line is a group of a source IP address and a destination IP address or IP packet set as a voice IP packet. It can be defined as a label of an additional MPLS scheme. In addition, in the case of other terminals such as an IP terminal, voice moving picture data or a fax data terminal, the communication line is a communication line for data transmission for an IP terminal, a voice moving picture transmission / reception terminal or a communication line for fax data transmission.

Next, the connection server 1-5 sends the initial address message IAM to the connection server 1-7 (step Y2), and at the same time transitions to the standby state of the address completion message ACM described later, and waits for the ACM wait timer. Start up. The relay access server 1-7 receives the IAM and sends the IAM to the access server 1-6 (step Y3). The connection server 1-6 checks the contents of the received IAM and checks whether the communication line is set to the media router 1-4 to which the terminal 1-2 having the destination telephone number is connected, that is, the media. It is checked whether the router 1-4 allows the incoming call of the connection request call, and when the incoming call is allowed, a call setting request is made to the media router 1-4 (step Y4), and the media router 1-4. Requests the terminal 1-2 for call setup (step Z4), and the connection server 1-6 forms an IP packet for notifying that the IAM has been received. This IP packet (called an address completion message (ACM)) is returned to the relay access server 1-7 (step Y5), and the ACM passes the relay access server 1-7 and the relay access server 1-5. (Step Y6). When the access server 1-5 receives the ACM, the access server 1-5 stops the previously set ACM wait timer. If the ACM waiting timer expires before the ACM is received, the call line is released. The ACM may also receive a line number (CIC) from the IAM and hold it inside the ACM, or the ACM may form and hold a line number from the group of the source telephone number and the destination telephone number inside the ACM in step Y5.

The terminal 1-2 sends a ringing tone of the connection request call to the media router 1-4 (step Z7), and the media router 1-4 makes a connection request call incoming call of the terminal 1-2. It transmits to the connection server 1-6 (step Y7), and the connection server 1-6 forms an IP packet informing that the terminal 1-2 is in the middle of receiving a connection request call. This IP packet is called an IP packet containing a call pass message (CPG) or simply a call pass message (CPG). The access server 1-6 sends a call passing message (CPG) to the relay access server 1-7 (step Y8), and the relay access server 1-7 sends the received CPG to the access server 1- 1. 5) (step Y9), the access server 1-5 receives the CPG, and the access server 1-5 sends the terminal router 1-2 from the contents of the CPG to the media router 1-3. The media router 1-3 is notified that this call is being made (step Y10), and the media router 1-3 is notifying the terminal 1-1 of the ringing tone (step Z10). In addition, in step Y5, the CPG may form a line number from the group of the source telephone number and the destination telephone number and hold it inside the CPG.

When the terminal 1-2 responds to the call setup request in step Z4 (step Z11), the media router 1-4 notifies the connection server 1-6 that the terminal 1-2 responds ( Step Y11), the connection server 1-6 forms an IP packet indicating that the terminal 1-2 responded to the request for call setting. This IP packet is referred to as an IP packet containing an acknowledgment message (ANM) or simply an acknowledgment message (ANM). The connection server 1-6 sends the generated ANM to the relay connection server 1-7 (step Y12), and the relay connection server 1-7 sends the received ANM to the connection server 1-5. (Step Y13). The connection server 1-5 notifies the media router 1-3 that the destination terminal 1-2 responds (step Y14), and the media router 1-3 notifies the terminal of the ring tone being transmitted. 1-1) (step Z14) of the IP packet having the digital media using the communication line for the terminal-to-terminal communication specified by the line number (CIC) between the terminal 1-1 and the terminal 1-2. Transmission and reception are enabled, and the flow shifts to the call phase (call state) (step Y15). In addition, in step Y5, the ANM may form a line number from the group of the source telephone number and the destination telephone number and hold it inside the ANM. The disconnect request of the terminal 1-1 is notified (step Z16), the media router 1-3 notifies the connection server 1-5 of the interrupt request (step Y16), and the terminal 1 -1) to notify cut confirmation (step Z18).

Upon receiving the disconnect request, the access server 1-5 identifies the line number CIC from the group of the source telephone number and the destination telephone number to form an IP packet indicating a release request REL of the communication line. This IP packet is called an IP packet including a release (REL) or simply a release message (REL). The release message REL includes a line number CIC, which sends the release message REL to the relay access server 1-7 (step Y17), and completes the recovery completion indicating the completion of the disconnect request. It returns to (1-3) (step Y18). The relay connection server 1-7 sends the release request REL to the connection server 1-6 (step Y19), and forms an IP packet indicating completion of the release request REL. This IP packet is called an IP packet including a release complete (RLC) or simply a release complete message (RLC). This release completion (RLC) is returned to the connection server 1-5 (step Y20).

When the connection server 1-6 receives the release request REL, the connection server 1-6 sends a disconnect request to the media router 1-4 (step Y21), and release completion (RLC) means that the release request REL is completed. To the relay connection server 1-7 (step Y22). When the media router 1-4 receives the disconnect request, it notifies the terminal 1-2 of the disconnect instruction of the connection request call (step Z22), and completes the blocking completion indicating that the disconnect instruction has been performed. It returns to the connection server 1-6 (step Y23). The terminal 1-2 notifies the media router of completion of recovery (step Z23). In the process of terminating the terminal-to-terminal communication, a request for disconnection of the terminal-to-terminal communication may be sent from the terminal 1-2 to the media router 1-4, which is in the same order as described above. It is also possible to control the communication connection between terminals between the access servers 1-5 and 1-6 without the relay access server 1-7. The connection servers 1-5 and 1-6 receive the line number (CIC), the communication time, and the telephone number after the end of the inter-terminal communication between the terminals 1-1 and 1-2, that is, at steps Y18 and Y22. The communication records between terminals can be collected and recorded in the access server, and used for billing and operation management.

In the terminal-to-terminal communication connection control described above, in the case where the terminal is a telephone, the digital media is digital voice and the media communication is telephony, and in the case where the terminal is an IP terminal (a terminal having a function of transmitting and receiving IP packets), In the case where the digital still image is digital still image and the media communication is the IP data communication, and the terminal is the voice moving picture transmission / reception terminal, the digital media is the digital voice moving picture and the media communication is the voice moving picture communication. The media is a digitized fax image and the media communication is a fax communication. In addition, the telephone number for identifying the communication counterpart terminal may be a terminal identification number individually determined for identifying the communication counterpart terminal, for example, a terminal unique number valid only inside a specific communication network.

In addition, various modifications can be made to the method of communication connection control between terminals between the media router and the access server and between the access server, and it is also possible to omit the start of the ACM wait timer in step Y2, which will be described in the embodiments. .

The present invention relates to a terminal-to-terminal communication connection control method using an IP transmission network, the object of the present invention is to perform a multimedia IP communication between a first IP terminal and a second IP terminal, the first IP terminal is the second IP terminal; The IP packet including the host name of the IP terminal is transmitted to the domain name server in the integrated IP transport network via the network node device via the domain name server in the media router. 2 An IP address corresponding to 1: 1 of the host name of the IP terminal is returned to the first IP terminal via the domain name server inside the media router or directly, and the first IP terminal is transmitted to the second IP terminal. When the IP packet is transmitted, the second IP is transmitted via a media router to which the first IP terminal is connected, and via at least one router in a network node device and an IP transmission network. Reach another network node apparatus connected to sense, via the communication line is achieved by via another media router, using the domain name server, so that the IP packets sent to the IP terminal.

In addition, the above object of the present invention is to provide a handset of the first non-independent IP telephone and to perform telephone communication between the first non-independent IP telephone and the second non-independent IP telephone. An IP packet notifying a call is sent, a first H323 end point inside the first media router detects the IP packet, returns a reply IP packet to the first non-standalone IP phone, and the first non-standalone IP phone. Wherein the IP packet containing the telephone number of the second first non-standalone IP telephone is passed through a first H323 end point to a first domain name server inside the first media router, and the first media router crosses a communication line. A first network node device is connected to the first network node device, and the first network node device transmits the IP packet to a second domain name server in the integrated IP transport network. The second IP address corresponding to the telephone number of the first non-standalone IP telephone is directly returned to the first H323 terminal via the first domain name server or not via the first domain name server. And the first H323 terminating portion generates an IP packet having a first IP address corresponding to 1: 1 as the source IP address and a second IP address as a destination IP address. When transmitting, the first network node device reaches another second network node device to which the second first non-standalone IP telephone is connected via one or more routers in the IP transmission network, and the other network node via a communication line. 2 is sent to a second H323 end point within the media router to which the second first non-standalone IP telephone is connected.

When a first user starts a phone call, the first non-standalone IP telephone includes a telephone voice digitally expressed with the first IP address as the source IP address and the second IP address as the destination IP address. Send an IP packet, and the IP packet passes the first H323 terminator and passes through the first network node apparatus, one or more routers in the IP transmission network, the second network node apparatus, and the second H323 terminator; When the second non-standalone IP telephone is sent to a second non-standalone IP telephone and the second user generates voice, the second non-standalone IP telephone sets the second IP address as the source IP address, and the first IP address as the destination IP address. And transmits an IP packet including a digitally expressed telephone voice, the IP packet passing through the second H323 end device to a second network node device and at least one inside the IP transmission network. Router, the first network node apparatus, the first past the H323 termination unit is sent to the first stand-alone non-IP telephone.

When the first user sets the handset for terminating the telephone communication, if the first IP address is used as the source IP address and the second IP address is the destination IP address, an IP packet indicating the end of the telephone communication is generated and sent; When the first H323 end device, the first network node device, the one or more routers in the IP transmission network, the second network node device, the second H323 terminal device is sent to the second non-standalone IP telephone, 2 When the user knows that the telephone communication has been terminated and the handset is released, the user generates an IP packet for confirming the end of the telephone communication by using the second IP address as the source IP address and the first IP address as the destination IP address. When transmitting, the IP packet passes the second H323 end device to the second network node device, one or more routers in the IP transmission network, the first network node device, The telephone communication is sent to the first H323 terminating device, the telephone communication between the first non-standalone IP telephone and the second non-standalone IP telephone is terminated, and the H323 terminal sends an IP packet transmitted to the second non-standalone IP telephone. Then, via the network node device, one or more routers inside the IP transmission network, to reach another network node device to which the second non-independent IP telephone is connected, enter another media router via a communication line, and then enter its H323 terminal. This is accomplished by sending an IP packet to the second non-standalone IP telephone.

The present invention applies a multicast technique to a means for setting an address management table in a network node device in an IP transmission network and registering an address of a terminal in the address management table (Japanese Patent Application No. Hei 11-128956). Explain. A network node device is installed in the IP transport network using the IP transport network as a network managed and operated by a telecommunications company, and IP address transmission by multicast with improved information security is realized by registering an IP address of an IP terminal in the network node device. Upon receipt of an IP packet containing an unregistered multicast IP address, the IP packet is discarded (IP address filtering operation).

Referring to FIG. 2, network node devices 1-11 to 1-14 and routers 1-15 to 1-20 are installed in the IP transport network 1-10. Network node devices and routers are connected directly by IP communication lines or indirectly via network node devices or routers. IP terminals 1 -21 to 1-27 having an IP packet transmission / reception function are connected to a network node device by an IP communication line. The IP terminal does not allow direct connection to the router. The network node apparatuses 1-11 to 1-14 register at least an IP address of the IP terminal information to which the node apparatus is connected in the node apparatus.

In the first IP packet acceptance check, it is checked whether the destination IP address in the header of the external IP packet entering the IP transmission network is registered in the address management table of the node apparatus. If the destination IP address is not registered, the IP is checked. Discard the packet. As a second IP packet acceptance check, it is checked whether the source IP address in the header of the external IP packet entering the IP transmission network is registered in the address management table of the node apparatus. If the source IP address is not registered, the IP packet is discarded. do. When the destination multicast address is registered in the address management table of the network node device as the first address registration check, and the destination multicast address in the header of the external IP packet entering the network node device is not registered in the address management table. In addition, the network node device discards the IP packet to prevent an unexpected IP packet from being mixed inside the IP transmission network. By not allowing the multicast sender's address registration in the address management table of the recipient network node device, the ACK packet for acknowledging IP packet receipt from the multicast IP packet receiver to the multicast IP packet sender cannot pass through the network node device. In addition, congestion of the IP transmission network due to ACK implosion of the ACK packet can be prevented.

Also, do not allow the IP address of the router to be registered as a destination address so that dangerous IP packets such as rewriting of multicast tables are not sent from outside the IP transport network to routers inside the IP transport network, or for multicast inside the IP transport network. By not allowing the registration of the IP address of the operation management server, access to the operation management server inside the IP transmission network from the outside of the IP transmission network is disabled, thereby improving information security. As the second address registration check, the source of the IP packet including the multicast data is restricted to prevent the cheating from occurring. In addition, when cheating is performed, it is easy to specify the source of the IP packet, and the information security of the IP transmission network can be improved.

Substituting IP encapsulation and IP decapsulation as described in embodiments of the invention with encapsulation or decapsulation in less than three layers of the communication layer, for example, encapsulation or decapsulation by the header of an optical HDLC frame in the second layer of the communication layer. It is possible to substitute by. In addition, it is also possible not to include the sender internal address in the header provided by encapsulation and decapsulation, that is, simple encapsulation and simple decapsulation applying a simple header. In simple encapsulation, an address management table having the same function as that used in encapsulation or decapsulation is used. It demonstrates using FIG.

Block 2300 is an IP network, reference numerals 2301, 2302, 2303 and 2304 denote network node devices, reference numerals 2301-1, 2302-1, 2303-1 and 2304-1 denote address management tables and reference numerals 2301-2 and 2301, respectively. -3, 2302-2, 2302-3, 2303-2, 2303-3, 2304-2, and 2304-3 are the contacts (logical terminals) of the terminal of the communication line and the network node device, respectively, and the internal address "IA1" , "IA2", "IA3", "IA4", "IA5", "IA6", "IA7", and "IA8" are given. Reference numerals 2306-1 to 2306-8 denote IP terminals having a function of transmitting and receiving IP packets, and have external IP addresses "EA1" to "EA8", respectively. Reference numerals 2307-1 to 2307-4 denote routers. The network node device or router is connected directly or indirectly via a communication line via a communication line, and the terminal is connected to the network node device via a communication line. In the description of FIG. 357, the header portion of the IP describes only the IP address portion and other items are omitted.

When the terminal 2306-1 transmits an IP packet 2310 having a source address " EA1 " and a destination address " EA3 ", and the network node device 2301 receives the IP packet 2310, the IP packet 2310. Confirm that the internal address assigned to the input logical terminal of the communication line is "IA1" and that the destination external IP address of the IP packet 2310 is "EA3", and that the address management table 2301-1 is internal. Search for a record that initially has a source internal IP address of " IA1 " and a destination external IP address of " EA3 ", and furthermore, a source external IP address in IP packet 2310 within the detected record. Check whether "EA1" is included.

In this example, the first row of the address management table 2301-1 is "EA1", "EA3", "IA1", and "IA3", and the IP packet is obtained using "IA3" of the address in the record. A simple header is given to 2310, and an inner packet 2313 is formed (simple encapsulation). However, the simple header does not include the sender internal address "IA1". The formed inner packet 2313 arrives at the network node device 2302 via routers 2307-1 and 2307-2. The network node device 2302 sends the external IP packet 2317 (same content as the IP packet 2310) obtained above to the communication line except for the simple header of the received internal packet 2313 (simple decapsulation). IP terminal 2306-3 receives IP packet 2317. Then, the first record "EA3, EA1, IA3, IA1" of the address management table 2302-1 transmits the IP packet by the same method as described above in the opposite direction to the above description, that is, the terminal 2306-3. To transmit an IP packet to the terminal 2306-1.

When simple encapsulation is performed in the network node device 2301, it is omitted to check whether "EA1" is included as a source external IP address in the IP packet 2310 in the record detected in the address management table 2301-1. You may. In the case of omitting the investigation of "EA1", each record in the address management table 2301-1 can be made to not include the source IP address externally. In addition, for the two external IP addresses (source IP address and destination IP address) in each record of the address management table 2301-1, a simple encapsulation technique according to the same principle as the address mask technique described later can be applied.

Another example of transmitting an IP packet will be described. When the terminal 2306-5 transmits an IP packet 2312 having a source address "EA5" and a destination address "EA4", and the network node device 2303 receives the IP packet 2312, the IP packet 2312. Confirm that the internal address assigned to the input logical terminal of the communication line is "IA5" and that the destination external IP address of the IP packet 2312 is "EA4", and the inside of the address management table 2303-1 is checked. The record is first searched for a record whose source IP address is " IA5. "In this case, the first row of records " Mask7, EA7x, IA5, IA7 " and the second row " of the address management table 2303-1. Mask4, EA4x, IA5, IA4 "correspond to the record of the first row, and the mask " Mask7 " and the result of " and " of the destination external IP address " EA4 " In order to check whether it matches the destination external IP address "EA7x" (Equation 4 below), The result of the "and" operation of the destination external IP mask "Mask4" for the destination and the destination external IP address "EA4" in the external IP packet 2312 for the next record in the second row is not the destination outside the second record. It checks whether it matches the IP address "EA4x" (Equation 5 below), but in this case it matches.

If ("Mask7" and "EA4" = "EA7x")… (4)

If ("Mask4" and "EA4" = "EA4x")… (5)

In this example, the second row of the address management table 2303-1 is "Mask4, EA4x, IA5, IA4" from above, and is a simple header in the IP packet 2312 using "IA4" of the address in the record. To form an inner packet 2314 (simple encapsulation). However, the simple header does not include the sender internal address "IA5". The formed inner packet 2314 reaches the network node device 2302 via routers 2307-3, 2307-4, and 2307-2. The network node device 2302 sends the external IP packet 2318 (same content as the IP packet 2312) obtained by the above, except for the simple header of the received internal packet 2314 (simple decapsulation). IP terminal 2306-4 receives IP packet 2318.

Next, the IP packet 2311 sent from the terminal 2306-2 to the terminal 2306-7 is recorded in the second row of the address management table 2301-1 in the network node device 2301-1, " EA2, " EA7, IA2, IA7 "are used to encapsulate the liver in the same manner as above to form an internal capsule 2316, and reach network node device 2304 via routers 2307-1, 2307-2, and 2307-4. Then, the network node device 2304 removes the simple header of the received internal packet 2316 (simple decapsulation), and transmits the external IP packet 2319 (same content as the IP packet 2311) obtained above to the communication line. The IP terminal 2306-7 receives the IP packet 2319.

The address mask scheme is the same principle as the address mask scheme described with reference to FIG. As another example of encapsulation and decapsulation by simple headers, known MPLS levels by the MPLS technique can be used. Here, the MPLS level includes a destination internal address but no sender internal address.

Next, the IP packet 2321 sent from the terminal 2306-9 to the terminal 2306-8 is stored in the second row of the records " Msk8, EA8y, " IA8 &quot; is used to encapsulate the liver in the same manner as above to form an internal capsule 2322, reach network node device 2304 via router 2307-4, and network node device 2304 receive the received internals. Except for the simple header of the packet 2232 (simple decapsulation), the external IP packet 2323 (same content as the IP packet 2321) obtained by the above is sent to the communication line, and the IP terminal 2306-8 transmits the IP. Receive packet 2319.

358 shows the format of an inner packet (also called an inner frame) formed in the simplified encapsulation. The inner packet has a form in which a simple header is attached to the outer IP packet, and the simple header includes a destination internal address and an information area. However, it does not include the sender internal address. The information area contains information (protocol, etc.) regarding the payload area of the inner packet. Next, another embodiment of the simplified encapsulation and decapsulation will be described with reference to FIGS. 359 and 360. Reference numerals 2351-1 to 2351-7 denote IP terminals, reference numerals 2352-1 to 2352-7 denote terminals having an external IP address "EA1", and reference numerals 2353-1 to 2353-7 denote external IP addresses "EA2". It is a terminal having. Reference numerals 2354-1 to 2354-7 denote internal packets (internal frames). Reference numerals 2355-1 to 2355-7 and 2356-1 to 2356-7 denote network node devices. Reference numerals 2359-1 to 2359-7 denote contact points (logical terminals) of the communication line and the network node device, and are assigned an internal address "IA1". Reference numerals 2360-1 to 2360-7 denote contact points (logical terminals) of the communication line and the network node device, and are assigned an internal address "IA2". Reference numerals 2357-1 to 2357-7 and 2358-1 to 2358-7 denote address management tables. The terminal and the network node device, the network node device and the other network node device is connected by a communication line, the IP packet is transmitted and received between the terminal and the network node device, the internal packet (internal frame) is transmitted between the network node device. .

When the terminal 2352-1 transmits an IP packet having a source address "EA1" and a destination address "EA2", and the network node device 2355-1 receives the IP packet, the IP packet is entered. Confirm that the internal address assigned to the logical terminal at the circuit end is " IA1 " and the destination external IP address of the IP packet is " EA2. &Quot; The record whose address is " IA1 " and which " EA2 " In this example, the first row of records from the address management table 2357-1 is "EA2, IA1, IA2", and a simple header is given to the IP packet using the address "IA2" in the record. Packet 2354-1 is formed (simple encapsulation). The formed inner packet 2354-1 reaches the network node device 2356-1 via a communication line. The network node device 2356-1 transmits the external IP packet obtained by the above to the communication line except for the simple header of the received internal packet 2354-1 (simple decapsulation), and the IP terminal 2353-1. Receive the recovered IP packet.

When the terminal 2352-2 transmits an IP packet having a source address "EA1" and a destination address "EA2", and the network node device 2355-2 receives the IP packet, a communication line to which the IP packet is input. Regardless of the internal address assigned to the terminal logical terminal, it is confirmed that the source external IP address of the IP packet is " EA1 " and the destination external IP address is " EA2 " Search. In this example, the first row of records from the address management table 2357-2 is "EA1, EA2, IA2", and a simple header is given to the IP packet using the address "IA2" in the record. Form packet 2354-2 (simple encapsulation). The formed inner packet 2354-2 reaches the network node device 2356-2 via a communication line. The network node device 2356-2 transmits the external IP packet obtained by the above to the communication line except for the simple header of the received internal packet 2354-1 (simple decapsulation), and the IP terminal 2353-2. Receive the recovered IP packet.

When the terminal 2352-3 transmits an IP packet having a source address "EA1" and a destination address "EA2", and the network node device 2355-3 receives the IP packet, the communication line to which the IP packet is input. Irrespective of the internal address assigned to the terminal logical terminal, it is confirmed that the destination external IP address of the IP packet is "EA2", and the inside of the address management table 2357-1 is searched to find the next destination external IP address. Search for records containing "EA2".

In this example, the records are "EA2, IA2" in the first row from the top of the address management table 2357-1, and a simple header is given to the IP packet using "IA2" of the address in the record. -3) (simple encapsulation). The formed inner packet 2354-3 reaches the network node device 2356-3 via a communication line. The network node device 2356-1 transmits the external IP packet obtained by the above to the communication line except for the simple header of the received internal packet 2354-3 (simple decapsulation), and the IP terminal 2353-3. ) Receives the IP packet.

When the terminal 2352-4 transmits an IP packet having a source address "EA1" and a destination address "" EA2 ", and the network node device 2355-4 receives the IP packet, the IP packet is entered. Confirming that the internal address assigned to the logical terminal at the circuit termination is "IA1" and the external IP address of the destination of the IP packet is "EA2", the inside of the address management table 2355-4 is searched to find the source of transmission. The record with the internal IP address "IA1" is searched. In this case, the first row of records "Msk1, EA1x, Msk2, EA2x, IA1, IA2" from the top of the address management table 2357-4 corresponds to the first one. Check whether the result of the "and" operation of the mask "Msk2" and the destination external IP address "EA2" in the inputted external IP packet coincides with the destination external IP address "EA2x" in the first record for the row record ( Equation 6) below, and also the source IP address mask "M check whether the result of the "and" operation of sk1 "and the source external IP address" EA1 "in the external IP packet matches the destination external IP address" EA1x "in the same record (Equation 7 below). .

If ("Msk2" and "EA2" = "EA2x")… (6)

If ("Msk1" and "EA1" = "EA1x")… (7)

In this example, the first row is the first row of the address management table 2357-4, and a simple header is given to the external IP packet using the address " IA2 " (Simple encapsulation). The formed inner packet 2354-4 arrives at the network node device 2356-4 via a communication line. The network node device 2356-4 transmits the external IP packet obtained by the above to the communication line except for the simple header of the received internal packet 2354-4 (simple decapsulation), and the IP terminal 2235-3. 4) receives the IP packet.

When the terminal 2352-5 transmits an IP packet having a source address "EA1" and a destination address "EA2" and the network node device 2355-5 receives the IP packet, the terminal 2352-4 receives the IP packet. Similar to the case of transmitting an IP packet with a source address "EA1" and a destination address "EA2", the difference is that no "and" operation of the destination external IP mask and the destination external IP address in the external IP packet is performed. Is the same, but otherwise.

In a case where the terminal 2352-6 transmits an IP packet having a source address "EA1" and a destination address "EA2" and the network node device 2355-6 receives the IP packet, the terminal 2352-4 Similar to the case of transmitting an IP packet having a source address "EA1" and a destination address "EA2", the difference is that the internal address assigned to the logical terminal of the communication line end to which the IP packet is input is not confirmed. Otherwise it is the same.

In a case where the terminal 2352-7 transmits an IP packet having a source address "EA1" and a destination address "EA2", and the network node device 2355-7 receives the IP packet, the terminal 2352-5 ) Is similar to the case of transmitting an IP packet having a source address "EA1" and a destination address "EA2", and the difference is that the internal address assigned to the logical terminal of the communication line end inputted by the IP packet is confirmed. It does not, and the others are the same.

EXAMPLE

In the present invention, Japanese Patent Application No. Hei 11-128956 or No.-7 common line signaling method by the present applicant, "JT-H323 gateway conforming to ITU-T Recommendation H 323 ANNEX D", "SIP telephone protocol" In addition, some combinations or changes of various functions disclosed in Example-36 of Japanese Patent No. 3084681 are introduced, and a media router, a gateway, and an IP network service operation management server are introduced to configure and operate the media router and gateway, By specifying the types of IP packets used for terminal-to-terminal communication using a media router or gateway, and the functions that the IP network service operation management server should have, the terminal-to-terminal communication connection control method based on the IP transmission network is realized.

According to Japanese Patent Application No. Hei 11-128956, the integrated IP transport network includes a plurality of IP transport networks, that is, an IP data network, an IP telephone network, an IP voice / image network, At least two best effort networks, IP data multicast networks, IP base TV broadcast networks, at least two network node apparatus, The node device is connected to any one or more networks of the IP transmission network via the communication line, and the network node device terminal of the network node device is connected to a terminal outside the integrated IP transmission network via the communication line.

In the present invention, the integrated IP transport network includes one or more gateways therein or is connected to one or more media routers directly or indirectly to a media router inside a LAN, over a communication line connected to a network node device outside thereof. The gateway and the media router are a kind of router having a function of directly connecting and accommodating an IP terminal, an IP telephone, an IP audio visual apparatus, and the like. Access control of end-to-end communication using an IP transport network between terminals is performed by a gateway or a media router and by using a domain name server inside the integrated IP transport network. In order to register and record the terminal in the IP transmission network, at least the address of the terminal is recorded and held in an address management table inside the network node device or in a domain name server installed in the IP transmission network. An IP network service operation management server is installed in each IP transport network to manage the operation of the IP transport network, the services provided by the IP transport network, and the network resources such as routers and communication lines for each communication provider.

The type of the IP network operation management server may be determined for each IP transmission network. For example, an IP data service operation management server (DNS) that collectively manages IP data communication in the IP data network may be used. The best support network in the best voice network The IP telephone service operation management server (TES) which manages collectively The IP voice image service operation management server (AVS) which manages voice video communication collectively in the IP voice video network Best effort service operation management server (BES) which manages communication collectively, IP data multicast service operation management server (DMS) which manages IP data multicast communication collectively in IP data multicast network An IP base TV broadcast service operation management server (TVS) for collectively managing IP base TV broadcasts may be installed in the TV broadcast network. The service operation management server for each IP transport network may be divided into a network service server dedicated to managing network services provided by the IP transport network and a network operation management server dedicated to managing network resources.

EMBODIMENT OF THE INVENTION Below, the Example of this invention is described with reference to drawings.

1. First embodiment using a media router:

In Fig. 3, reference numeral 2 denotes an integrated IP transmission network, reference numeral 3 denotes an IP data network, reference numeral 4 denotes an IP telephone network, reference numeral 5-1 denotes an IP voice video network, reference numeral 5-2 denotes a best effort network, and reference numerals. 6-1 denotes a range of IP transmission networks managed by telecommunication company X, and reference numeral 6-2 denotes a range of IP transmission networks managed by telecommunication company Y. Reference numerals 7-1, 7-2, 7-3, 7-4, 8-1, 8-2, 8-3, and 8-4 are network node devices, respectively, and reference numerals 9-1 and 9-2 It is a gateway. Reference numerals 10-1 to 10-8 denote communication lines, reference numerals 11-1 to 11-10 denote IP terminals, reference numerals 12-1 and 12-2 denote independent IP telephones, and reference numerals 13-1 to 13-4 denote Non-Independent IP Phones, 16-1 to 16-4, are non-independent IP voice imagers.

The network node device is any one of an IP transmission network via a communication line, that is, one of an IP data network 3, an IP telephone network 4, an IP voice video network 5-1, and a best effort network 5-2. An IP terminal 11-1 or 11-2, a standalone IP telephone 12, connected to one or more networks and external to the integrated IP transport network via communication lines 10-1 to 10-8. -1 or 12-2), media router 14-1 or 14-2, LAN 15-1 or 15-2, or the like. The media routers 14-3 and 14-4 are provided inside the LAN 15-1 and the LAN 15-2, and are indirectly connected to the network node device. The media routers 14-1 to 14-4 include non-independent IP phones 13-1, 13-2, and 13-4, non-independent IP voice image devices 16-1, 16-2, 16-3, Analog telephones 18-1 to 18-4 are directly connected and accommodated. The other analog telephones 18-5 or 18-6 are connected to the gateway 9-1 or 9-2 via the public switched telephone network 26-1 or 26-2. The gateway 9-1 is connected to the network node device 8-4 via a communication line, and the gateway 9-2 is connected to the network node device 7-4 via a communication line.

Reference numerals 19-1 to 19-19 denote routers for transmitting IP packets, respectively, and reference numerals 26-1 and 26-2 denote public switched telephone networks (hereinafter referred to as "PSTN"). The media router 14-1 is connected to the network node device 8-2 via the communication line 10-1, and the media router 14-2 is connected to the network node via the communication line 10-5. Connected to the device 7-2, the LAN 15-1 is connected to the network node device 8-4 via the communication line 10-3, and the LAN 15-2 is connected to the communication line 10; It is connected to the network node device 7-4 via -7).

The analog telephone 18-5 is a network node device 8-4 via a telephone line 17-3, a public switched telephone network 26-1, a telephone line 17-1, and a gateway 9-1. Analog telephone 18-6 is connected to telephone line 17-4, public switched telephone network 26-2, telephone line 17-2, and gateway 9-2. 7-4). The media router 14-1 includes a router 20-3, a connection controller 22-1, an H323 terminal 23-1, and an SCN boundary 24-1. The connection control unit 22-1 is connected to the H323 terminal unit 23-1, and the H323 terminal unit 23-1 is connected to the SCN boundary unit. Similarly, the media router 14-2 includes a router 20-4, a connection control unit 22-2, an H323 termination unit 23-2, and an SCN boundary unit 24-2.

The router 20-1 in the LAN 15-1 is connected to the network node device 8-4 through the communication line 10-3. The LAN 15-1 is connected to the IP terminal 11-4 and the media router 14-3 via a LAN communication line such as Ethernet. The media router 14-3 is connected to the IP terminal 11-5, the non-independent IP audio image device 16-2, and the analog telephone 18-2 via a communication line. Similarly, the router 20-2 in the LAN 15-2 is connected to the network node device 7-4 via the communication line 10-7. The LAN 15-2 is connected to the IP terminal 11-8 and the media router 14-4 via a LAN communication line such as Ethernet. In addition, the media router 14-4 is connected to the IP terminal 11-9, the non-independent IP telephone 13-4, and the analog telephone 18-4 via a communication line.

Reference numerals 21-1 to 21-5 denote routers for transmitting IP packets between the range 6-1 managed by the communication company X and the range 6-2 managed by the communication company Y. Reference numerals 27-1 and 27-2 denote an asynchronous transfer mode network (ATM), reference numeral 27-3 denotes an optical communication network, and reference numeral 27-4 denotes a frame relay (FR) switching network, and each transmits an IP packet. This embodiment is used as a high speed trunk line network. The ATM network, the optical communication network, and the frame relay switching network can be used as any element of a sub-IP network of an integrated IP transmission network.

IP data service operation management server 35-1, IP telephone service operation management server 36-1, IP voice image service operation server 37-1, and best effort service operation management server 38-1, respectively. It is managed by telecommunication company X and is inside the scope of the network managed by telecommunication company X (6-1). In addition, IP data service operation management server 35-2, IP telephone service operation management server 36-2, IP audio image service operation server 37-2, best effort service operation management server 38-2. Are each managed by telecommunication company Y, and are within the range 6-2 of the network managed by telecommunication company Y.

Various multimedia terminals connected to the outside of the integrated IP transmission network 2 through a communication line, i.e., an IP telephone or an IP audio visual apparatus, like other IP terminals, locate a location of the inside of the integrated IP transmission network 2 as an address for identifying the multimedia terminal. This can be specified by the host name as. The host name of the IP terminal or the multimedia terminal is the same as the host name of the computer used on the Internet, and is named corresponding to the IP address given to each IP terminal or the multimedia terminal. In the present invention, a telephone number assigned to an IP telephone or an IP audio visual apparatus is used as a host name of the IP telephone or IP audio visual apparatus.

Domain name server (hereinafter referred to as "DNS") holds 1: 1 correspondence information of host name and IP address, and when host name is presented, its main function is to return IP address and has the same function as used on the Internet. Have

The dedicated domain name server 30-1 of the IP data network is connected to the IP terminals 11-3, 11-1, 11-4, 11-6, etc., used in the IP data network connected to the network node device managed by the communication company X. 1 to 1 correspondence information of the host name and IP address assigned to each terminal, and the dedicated domain name server 30-4 of the IP data network is connected to the network node device managed by the communication company Y. 11-1, 11-2, 11-8, and the like, which are IP terminals used in an IP data network, contain 1: 1 correspondence information of host names and IP addresses assigned to respective terminals.

The IP telephone network dedicated domain name server 31-1 is a non-independent IP telephone 13-1, 13-3 or an analog telephone 18-1, 18 used in an IP telephone network connected to a network node device managed by communication company X. Host information (telephone number) assigned to these telephones and 1: 1 correspondence information of IP addresses, and the domain name server 31-2 dedicated to the IP telephone network. Host names assigned to these telephones for non-independent IP telephones 13-2, analog telephones 18-3, 18-4, 18-6, and the like used in the IP telephone network connected to the network node device managed by Y ( Phone number) and IP address 1: 1 correspondence information.

The voice video network-dedicated domain name server 32-1 is a non-independent IP voice video device 16-1 and an independent IP voice video device 12 used in an IP voice video network connected to a network node device managed by the communication company X. -3), the host name (IP audio image device number) assigned to these IP audio image apparatuses, and 1: 1 correspondence information of the IP address are stored, and an IP voice image network dedicated domain name server 32-2 is provided. ) Is a host name (IP voice) assigned to these IP audio image apparatuses for the non-independent IP audio image apparatuses 16-3 and 16-4 used in the voice image network connected to the network node apparatus managed by the communication company Y. And 1: 1 correspondence information of the image device number) and the IP address.

The domain name server 33-1 dedicated to the best effort network is an IP terminal 11-5 and a non-independent IP voice image device 16-2 used in the best effort network connected to the network node device managed by the communication company X. And the 1: 1 correspondence information of the host name and IP address assigned to these terminals, and the best-effort network dedicated domain name server 33-2 is connected to the network node device managed by the communication company Y. It holds 1: 1 correspondence information of host names and IP addresses assigned to these terminals for IP terminals 11-9 and 11-10, non-independent IP telephones 13-4, and the like used in the connected best effort network. have.

Next, the basic functions of the media router and gateway, which are the main elements of the present invention, will be described with reference to FIGS. 4 and 5.

The SCN terminal function block 802-0, the conversion function block 803-0, and the terminal function block 804-0 each correspond to the aforementioned SCN terminal function block 802, the conversion function block 803, and the terminal function block ( 804 includes functionality. The audio or video signal input from the analog telephone 41-3 via the SCN line 40-1 is converted into a digital data signal in the SCN terminal function block 802-0, and the conversion function block 803-0. The data format, the signal transmission / reception rule, and the like are converted, and the terminal function block 804-0 is converted into an IP packet format and transmitted to the IP communication line 40-2. The reverse flow, that is, the IP packet including the voice or image data input from the IP communication line 40-2 is decoded in the form of digital data in the terminal function block 804-0, and the conversion function block 803 is used. -0), the data format, the signal transmission / reception rule, and the like are converted, and the SCN terminal function block 802-0 is converted into a signal flowing through the SCN line, and the analog telephone 41-3 is passed through the SCN line 40-1. Is sent. SCN boundary 24-0 includes SCN terminal function block 802-0 and transform function block 803-0. The H323 terminal 23-0 includes a terminal function block 804-0, and the terminal function block 804-0 includes the above-described H323 termination function, whereby the H323 terminal 23-0 is connected to the terminal ( 41-2) and two-way communication can be performed via the communication line 40-5. The multimedia terminal 41-2 used in the present invention is an IP telephone or an IP audio apparatus that conforms to the H323 specification. The connection control part 22-0 is connected to the H323 terminal part 23-0 via the communication line 40-2, and is connected to the router 20-0 via the line 40-3. The router 20-0 is connected to the network node device 41-4 via the communication line 40-4, and is connected to the IP terminal 41-1 via the communication line 40-6. . An IP packet 810 as call control data, an IP packet 811 as net data constituting voice, and an IP packet 812 as net data constituting the image itself are delivered to the communication line 40-2.

The call control data includes a host name such as a telephone number or a personal computer. On the other hand, the IP packet 43 (FIG. 5) provided to the communication line 40-3 is a data format for notifying and inquiring a host name to DNS and obtaining a reply, that is, a DNS inquiry response format. For example, RFC 1996 A Mechanism for Prompt Notification of Zone Changes. The DNS query response function block 42 has a function of converting the H323 format call control data 810 into the DNS query response format data 43 and querying the DNS to obtain an IP address corresponding to the host name. In addition, the IP packet 811 constituting the voice and the IP packet 812 constituting the image itself pass through the connection control section 42 transparently.

Incorporating the above, the telephone number input from the analog telephone 41-3 is changed from the SCN boundary 24-0 to the digital telephone number and entered into the H323 terminal 23-0, or an H323 format IP telephone. The telephone number or host name of the multimedia terminal conforming to the H323 specification inputted from (41-2) is input to the H323 terminal 23-0 as the H323 format call control data 810, and the two telephone numbers are the communication line 40 -2) on the H323 format call control data 810, and is converted to the DNS inquiry response format 43 via the connection control section 22-0. In addition, since the call control data provided from the IP terminal 41-1 originally adopts the DNS inquiry response format 43 and does not need to use the functions of the connection control unit 22-0, the router 20-0 is directly used. ) Here, the router 20-0 combines the communication line 40-3 and the communication line 40-6 and simultaneously transmits an IP packet. In addition, the net data constituting the voice or the image itself in the IP packet 811 or 812 passes through the connection control unit 22-0 unchanged. The IP packet is transmitted and received between the network node device 41-4 and the router 20-0 via the line 40-4.

As a specific example of the DNS lookup response, when the IP telephone is given the telephone number " 81-47-325-3897 " and " 192.1.2.3 " of the IP address, the telephone number " 81-47-325-3897 " When DNS is returned, IP address "192.1.2.3" is returned or when the host name "host1.dname1.dname2.co.jp" and IP address "128.3.4.5" are given to the personal computer that is the IP terminal. When DNS is queried for the host name "host1.dname1.dname2.co.jp", DNS returns the IP address "128.3.4.5" of this personal computer.

The IP terminal 41-1, the multimedia terminal 41-2, and the analog terminal 41-3 can communicate by transmitting and receiving IP packets between them. In other words, the IP terminals 41-1 transmit and receive IP packets to and from the multimedia terminal 41-2 via the router 20-0, the connection controller 22-0, and the H323 terminal 23-0. It is possible to communicate and communicate with the analog telephone 41-3 and with each other via the SCN boundary 24-0. In addition, the multimedia terminal 41-2 can communicate with the analog telephone 41-3 via the H323 terminal 23-0 and the SCN boundary 24-0.

<< operation of media router >>

The operation of the media router 14-1 of the present invention will be described with reference to FIG. The router 20-3, which is one element of the media router 14-1, has a function of the router 20-0 of FIG. 4, and the connection control unit 22-1 of FIG. 22-0), the H323 termination 23-1 of FIG. 6 has the function of the H323 termination 23-0 of FIG. 4, and the SCN boundary 24-1 of FIG. Has the function of the SCN boundary 24-0. Reference numeral 48-1 of FIG. 6 has the same function as the above-described DNS. The RAS mechanism 49-1 registers and authenticates the terminal to the media router 14-1 ('registration' means connecting the terminal to the media router, and 'authentication' means that the terminal is normally connected according to the access permission conditions of the terminal). Means managing the internal state of the media router (e.g., managing the internal components and their usage collectively), and reference numeral 50-1 denotes a media router. (14-1) An information processing mechanism in charge of internal information processing, and reference numeral 51-1 denotes an operation input / output unit of the media router 14-1. Accordingly, the functions of the connection control unit 22-1, the H323 terminal unit 23-1, and the SCN boundary unit 24-1 of the media router 14-1 of FIG. 6 are connected to the connection control unit 22-0 of FIG. ), H323 termination 23-0, SCN boundary 24-0.

<< communication connection control between IP terminals >>

Next, the procedure of transmitting and receiving data stored in the IP packet from the IP terminal 11-3 to the IP terminal 11-7 will be described with reference to Figs. 6, 7 and 8-14. . The IP terminal 11-3 transmits its own address, that is, the sender IP address "A113" via the communication line 52-1, the address of the domain name server 48-1 inside the media router 14-1, i.e. The IP packet 45-1 shown in Fig. 9, which stores the destination IP address " A481 " and the host name " IPT-11-7 name " To 1). Here, the inquiry contents shown in the IP packet 45-1, that is, "IPT-11-7 name" are stored in the "query section" in the "DNS inquiry response format" shown in FIG. The domain name server 48-1 examines the contents of the received IP packet 45-1, passes through the communication line 10-1, and passes through the network node device 8-2 to the dedicated domain of the IP data network. The name server 30-1 is inquired (step ST10). When the domain name server 30-1 returns an IP packet including the IP address "A117" corresponding to 1: 1 with the host name "IPT-11-7 name" to the domain name server 48-1 (step) ST11), domain name server 48-1 returns IP packet 45-2 to IP terminal 11-3. In the above-described procedure, the network node apparatus 8-2 refers to the address management table 44-1 in FIG. 8 and registers the sender address " A113 " included in the received IP packet 45-1 in the address management table. Investigate whether or not In this case, the IP whose external IP address is " A113 " and the communication line identification symbol " Line-10-1 " is input from the communication line 10-1 in the second row above the address management table 44-1. Since it is a packet, it is confirmed that the IP terminal 11-3 has registered permission to communicate via the network node device. In addition, when not registered in the address management table 44-1, the network node device 8-2 can discard the received IP packet 45-1.

Next, the IP terminal 11-3 generates an IP packet 45-3 to be transmitted to the IP terminal 11-7 and transmits it to the network node device 8-2 via the router 20-3. When the network node device 8-2 transmits this IP packet 45-3 to the inside of the integrated IP transport network 1, the IP packet 45-3 is inside the IP data network 3 in FIG. A network node device 7-2 is reached through a communication line and a plurality of routers, that is, routers 19-1, 19-3, 21-1, 19-5, and 19-6. In this way, the network node device 7-2 provides the received IP packet 45-3 to the communication line 10-5 shown in Fig. 7 (step ST12), and the router 20-4 receives the IP packet. (45-3) is received and transmitted to the IP terminal 11-7 via the communication line 52-2. The IP terminal 11-7 which has received the IP packet 45-3 generates the reply IP packet 45-4 and sends it to the router 20-4 via the communication line. ) Via the network node device 7-2 and the network node device 8-2 via the IP data network 3 inside the integrated IP transmission network 2, and the communication line (step ST13). The IP packet 45-4 shown in FIG. 12 is provided to the IP terminal 11-3 via 10-1. In the above procedure, the IP terminal 11-3 and the IP terminal 11-7 can communicate by transmitting and receiving an IP packet.

In the communication procedure in the IP terminal described above, the domain name server 48-1 in the media router may be excluded from the media router 14-1. In this case, the IP terminal 11-3 is the source IP address "A113", the IP address "A301" of the dedicated domain name server 30-1 of the IP data network, and the host of the IP terminal 11-7 of the communication partner. The IP packet 45-5 storing the name "IPT-11-7 name" is transmitted to the domain name server 30-1. The domain name server 30-1 returns an IP packet 45-6 including the IP address " A117 " corresponding to 1: 1 in " IPT 11-7 name. &Quot; In addition, a technique for directly accessing the domain name server 30-1 except for the domain name server 48-1 in the media router is possible by a known technique related to the domain name server.

When the above step ST11 is finished, the IP terminals 11-3 and 11-7 are ready to start communication, and when the network node device 8-2 detects the IP packets 45-2 and 45-6, the IP is ready. An inter-terminal communication record, that is, a communication record between the IP terminal 11-3 and the IP terminal 11-7 is retained therein with the time, if necessary.

<< Communication Connection Control Between Non-Independent IP Phones >>

Next, a procedure of dialing a telephone number to perform telephone communication from the non-independent IP phone 13-1 to the non-independent IP phone 13-2 will be described. Here, the "non-independent IP telephone" refers to an IP telephone which connects to the media routers 14-1 and 14-2 for communication, and the "independent IP telephone" directly connects to the network node device without being connected to the media router. The IP telephone 12-1 or 12-2 in Fig. 3 will be described later in the communication procedure.

The non-independent IP telephone 13-1 of FIG. 6 is connected to the H323 terminal 23-1 via the communication line 53-1, and the non-independent IP telephone 13-2 of FIG. 7 is communicating. It is connected to the H323 terminal part 23-2 via the line 53-2.

Lifting the handset of the non-independent IP telephone 13-1 (off-hook), the IP packet 46-1 shown in FIG. 15 for notifying a call is transmitted to the communication line 53-1 shown in FIG. 6 (FIG. Step ST20 of step 6 and H323 terminal part 23-1 detect that a call was input from the communication line 53-1, and return the IP packet 46-2 of call confirmation (step ST21). Here, "CTL-Info-1" described in the payload (data portion) of the IP packet 46-1 is call control information, and "CTL-Info- described in the payload of the IP packet 46-2. 2 "is call confirmation information.

Next, when the user of the non-independent IP phone 13-1 dials and enters the telephone number of the non-independent IP phone 13-2 of the communication counterpart, the communication counterpart phone is inside the non-independent IP phone 13-1. IP packet 46, for example in the form of H.225 call control data, including a number (" Tel-13-2 name ") and a telephone number and IP address of the non-independent IP telephone 13-1. 3) is generated and transmitted to the H323 terminal 23-1 via the communication line 53-1. However, whether or not to include the telephone number and IP address of the non-independent IP telephone 13-1 in the IP packet 46-3 is optional. The H323 terminal 23-1 receives the IP packet 46-3 from the communication line 53-1, retrieves a record inside the media router status table 100-1 of FIG. -1), and in this case, "53-1" which is the first row record above the media router status table 100-1 is detected. Next, the telephone number " 81-3-1234-5679 " or the IP address " 32.3.53.1 " of the non-independent IP telephone 13-1 described in this record is read. If it is not included in the packet 46-3, the value described in the media router status table is not set even if the IP packet 46-3 is set or if information regarding the IP address or telephone number is entered. If it is a value, the IP packet 46-3 is discarded as error processing. Here is an example in which the specific numerical value of "A131" of the IP address of the non-independent IP telephone 13-1 is "32.3.53.1" (step ST22).

Next, the H323 end portion 23-1 receives the address of the non-standalone IP telephone 13-1, that is, the source IP address "A131", the address of the domain name server 48-1, that is, the destination IP address "A481." ", Sends the IP packet 46-4 which stored the communication party telephone number" Tel-13-2 name "to the domain name server 48-1 in the media router 14-1 of FIG. ST23). The domain name server 48-1 examines the contents of the received IP packet 46-4, and then the dedicated domain of the IP telephone network via the communication line 10-1 and the network node device 8-2. The IP packet 46-5 is transmitted to the name server 31-1 (step ST24). The dedicated domain name server 31-1 of the IP telephone network transmits an IP packet including the IP address " A132 " corresponding to 1: 1 with the host name " Tel-13-2 name &quot;. If it returns to (Step ST25), the domain name server 48-1 returns the IP packet 46-6 to the H323 terminal part 23-1.

Next, the H323 terminal 23-1 generates an IP packet 46-7 to transmit to the H323 terminal 23-2, and the network node device 8-2 via the router 20-3. (Step ST26), the network node device 8-2 transmits the IP packet 46-7 inside the integrated IP transmission network 2 of FIG. 3, and the IP packet 46-7 transmits the IP packet 46-7. The network node device 7-2 is reached through the routers 19-8, 19-9, 21-2, 19-11, and 19-13 in the telephone network 4. In this way, the network node device 7-2 sends the received IP packet 46-7 to the communication line 10-5, and passes through the router 20-4 to the H323 terminal 23-2. Receives the IP packet 46-7. The H323 terminal 23-2 interprets the IP packet 46-7 as a telephone call and performs the following two processes. The first step is to generate a reply IP packet 46-8 and return it to the router 20-4. The second step is to send the IP packet 46-7 to the communication line 53-2 shown in FIG. Is transmitted to the non-independent IP phone 13-2 via.

Referring to Fig. 7, the IP packet 46-8 generated by the first process passes through the communication line 10-5 (step ST27), and the network node device 7-2 and the IP telephone network ( 4) is reached to the network node device 8-2 via a communication line 10-1, to a router 20-3, and via a H323 terminal 23-1 to a non-independent IP. It is sent to the telephones 13-1, respectively. The non-independent IP phone 13-1 interprets that the communication partner is in a call by receiving the IP packet 46-8.

By the second process, the non-independent IP phone 13-2 sounds a ringing tone (call tone) by receiving the IP packet 46-7. The user of the non-independent IP telephone 13-2 hears this ring tone and picks up the handset of the non-independent IP telephone 13-2 (off-hook). In this way, the non-independent IP phone 13-2 generates an IP packet 46-9 and sends it to the line 53-2 (step ST28), and the H323 terminal 23-2 receives the IP packet 46 -9) to receive the network node device 8-2 via the network node device 7-2 and the IP telephone network 4, and to the router 20-3 via the communication line 10-1. Is sent to the non-independent IP phone 13-1 via the H323 termination unit 23-1, and a sound (response) informing that the telecom partner lifts the handset of the non-independent IP phone 13-2. As a result, the user of the non-independent IP telephone 13-1 is notified.

In step ST28, the IP packet 46-9 informing the start of the telephony communication between the information of the response, that is, the non-independent IP telephone 13-1 and the non-independent IP telephone 13-2, is transmitted. When the node device 7-2 or 8-2 detects the IP packet 46-9, the telephone communication start record, that is, the telephone between the non-independent IP telephone 13-1 and the non-independent IP telephone 13-2. A charge record that sets a part of the contents of the IP packet 46-9, such as a sender IP address, a destination IP address, a sender port number, a destination port number, and a detection time, inside the network node device to indicate that the communication has been started. You can keep it as a file.

When the user of the non-independent IP telephone 13-1 starts a telephony conversation, the non-independent IP telephone 13-1 generates an IP packet 46-10 containing digitized voice to communicate with the communication line 53-. 1) (step ST29). The voice packet 46-10 includes the H323 controller 23-1, the router 20-3, the network node device 8-2, the routers 19-8, 19-9, 21-2, 19-11, 19-13, through the network node device 7-2, the router 20-4, and the H323 termination unit 23-2, to the non-independent IP telephone 13-2. The sound of the user using the non-independent IP phone 13-2 is digitized and stored in the IP packet 46-11, and the reverse flow from that described above, that is, the H323 control unit 23-2 and the router 20-4. , Network node device 7-2, router 19-13, 19-11, 21-2, 19-9, 19-8, network node device 8-2, router 20-3, H323 It is sent to the non-independent IP telephone 13-1 via the termination part 23-1 (step ST30).

When the user of the non-independent IP phone 13-1 puts the handset on for the termination of telephony, the non-independent IP phone 13-1 generates an IP packet 46-12 indicating the end of the telephony communication to produce a communication line ( 53-1) (step ST31). The IP packet 46-12 includes the H323 controller 23-1, the router 20-3, the network node device 8-2, the routers 19-8, 19-9, 21-2, 19-11, 19-13, through the network node device 7-2, the router 20-4, and the H323 termination unit 23-2, to the non-independent IP telephone 13-2. When the user of the non-independent IP phone 13-2 knows that the telephone communication has been terminated and the handset is released, the user generates and sends an IP packet 46-13, and flows in the opposite direction to that described above, that is, the H323 control unit 23-. 2), router 20-4, network node device 7-2, router 19-13, 19-11, 21-2, 19-9, 19-8, network node device 8-2 Is sent to the router 20-3 and the H323 terminal 23-1 (step ST32).

In step ST32, call disconnection confirmation information, that is, an IP packet 46-13 indicating the end of telephony communication between the non-independent IP phone 13-1 and the non-independent IP phone 13-2, is transmitted. When the node device 8-2 or 7-2 detects the IP packet 46-13, the telephony end record, i.e., between the non-independent IP phone 13-1 and the non-independent IP phone 13-2. Part of the contents of the IP packet 46-13, e.g., source IP address, destination IP address, source port number, destination port number, and detection time of the telephony termination fact, is recorded inside the network node apparatus. You can keep it as a file.

According to the above procedure, the non-independent IP telephone 13-1 and the non-independent IP telephone 13-2 can perform telephone communication by transmitting and receiving an IP packet.

In the above-described communication procedure, except for the domain name server 48-1 in the media router from the media router 14-1, the above steps ST23 to ST25 may be replaced by steps ST23x and ST25x described below. That is, the H323 end portion 23-1 is the address of the non-independent IP telephone 13-1, that is, the source IP address "A131", the address of the dedicated domain name server 31-1 of the IP telephone network, that is, the destination IP. The IP packet 46-14 storing the address "A311" and the communication party's telephone number "Tel-13-2 name" is dedicated to the IP telephone network via the communication line 10-1 and the network node device 8-2. To the domain name server 31-1 to be used (step ST23x). The domain name server 31-1 transmits the IP packet 46-15 including the IP address " A132 " that corresponds 1: 1 to the communication counterpart phone number " Tel-13-2 name &quot; ) (Step ST25x).

In the process of steps ST23 to ST25 described above or steps ST23x and ST25x, the network node device 8-2 transmits the source address included in the IP packet 46-5 received via the communication line 10-1. By checking whether or not the combination of A481 "and the communication line identification symbol" Line-10-1 "is registered in the address management table 44-1 (FIG. 8), or the network node device 8-2 checks the communication line 10 The combination of the sender address " A131 " and the communication line identification symbol " line-10-1 " included in the IP packet 46-14 received via -1) is stored in the address management table 44-1 (FIG. 8). By checking whether it is registered, the non-independent IP telephone 13-1 is allowed to communicate via the network node device 8-2 from the communication line 10-1, that is, "communication permission registration". Check that there is.

<< Communication connection control between standalone IP phones >>

Since the non-independent IP phone 13-1 of FIG. 6 includes the termination function of the H323 termination unit 23-1, the non-independent IP phone 13-1 can be integrated with the connection control unit 22-1. Can be. For this reason, the non-independent IP phone 13-11 inside the independent IP phone 12-1 in Fig. 31 is connected to the direct connection control unit 22-11 via a communication line. The communication line 10-4 is shown from the connection control part 22-11, and is connected to the network node device 8-4 of FIG. The stand-alone IP telephone 12-1 and the stand-alone IP telephone 12-2 can perform telephone communication for transmitting and receiving IP packets, and the communication order is the non-standalone IP telephone 13-1 and the non-standalone IP telephone. The same as in step ST20 to step ST32 in which (13-2) performs telephone communication by transmitting and receiving an IP packet. The first difference is that since there is no domain name server 48-1 in the media router 14-1, step ST23 and step ST24 are integrated without passing through the domain name server 48-1. The second is that instead of the H323 terminations 23-1 and 23-2, these H323 terminations 23-1 and 23-2 are replaced by communication lines through which IP packets can pass. Is that.

<< between non-independent IP voice imager and non-independent IP voice imager >>

By transmitting and receiving an IP packet from the non-independent voice imager 16-1 to the non-independent IP imager 16-3, it is possible to perform a host name identifying the device by voice image communication for transmitting and receiving an IP packet. It is possible. The communication procedure is the same as that of step ST20 to step ST32 in which the non-independent IP telephone 13-1 and the non-independent IP telephone 13-2 use the dedicated domain name server 31-1 of the IP telephone network. The difference is that instead of using the dedicated domain name server 31-1 of the IP telephone network, the dedicated domain name server 32-1 of the IP voice video network in Fig. 7 is used, and instead of steps ST24, step ST44, step ST25 instead of step ST24. Is to run ST45. The non-independent voice imager 16-1 combines the host name of the non-independent voice imager 16-2 with the IP image-only domain name server 32-1 in the IP transmission network. The non-independent audio image device 16-1 is obtained by acquiring the IP address of -2) and then transmitting audio image data from the non-independent audio image device 16-1 to the non-independent audio image device 16-2. ) And voice image communication for transmitting and receiving voice image data between the non-independent voice image device 16-2.

<< between standalone IP voice video device and non-standalone IP voice video device >>

Since the non-independent IP audio image device 16-1 of FIG. 6 includes a termination function of the H323 termination unit 23-1, the non-independent IP audio image device 16-1 is connected to the connection control unit 22-1. It can be integrated. For this reason, the non-independent IP audio image device 16-12 in the standalone IP audio image device 12-3 shown in Fig. 32 is connected to the direct connection control unit 22-12 via a communication line. The communication line 10-9 is shown from the connection control part 22-12, and is connected to the network node device 8-4 of FIG.

The independent IP audio image device 12-3 and the non-independent IP audio image device 16-3 can perform voice image communication for transmitting and receiving IP packets, and the communication order is the non-independent IP audio image device 16-. Steps ST20 to 1) and the non-independent IP voice image device 16-3 perform voice image communication by transmitting and receiving IP packets using the dedicated domain name server 32-1 of the IP voice image network 5-1. It is the same as step ST32. The difference is that since there is no domain name server 48-1 in the media router 14-1, steps ST23 and ST24 are regarded as an integrated step without passing through the domain name server 48-1.

The network node device 8- is connected between the independent audio picture device 12-3 and the independent audio picture device 16-4 by connecting the independent IP voice picture terminal device 16-4 to the network node device 7-4. 4) Voice video communication for transmitting and receiving IP packets can be performed via the IP voice video network 5-1 and the network node device 7-4.

Viewing the standalone IP audio image device 12-3 as a selling means of a voice image product sales company that sells voice image goods, the non-independent IP voice image device 16-3 or the standalone IP voice image device 16-4. As a purchase means of a voice image product purchaser, a virtual market that enables the distribution of voice image products using an IP transmission network is realized. The purchaser orders the audio image goods to the sales company by the voice image journal and the sales company can send the digital audio image goods.

<< Communication Between Analog Phones >>

Referring to Figs. 3, 6, 7, and 33 to 47, the telephone number is dialed to make the telephone communication from the ordinary telephone, that is, the analog telephone 18-1 to the analog telephone 18-3, not the IP telephone. Explain the order.

The analog telephone 18-1 of FIG. 6 is connected to the SCN boundary 24-1 via the communication line 55-1, and the analog telephone 18-3 of FIG. 7 is connected to the communication line 55-. It is connected to SCN boundary part 24-2 via 2). When the handset of the analog telephone 18-1 is lifted (off-hook), a call analog signal is sent to the SCN boundary 24-1 via the communication line 55-1, and the SCN boundary 24-1 is received. Convert one call signal into digital data format. Next, the digital data 47-1 shown in FIG. 33 that notifies the call by converting the digital data transmission / reception rule or the like is generated and input to the H323 terminal 23-1 (step ST60 in FIG. 6). The H323 terminal 23-1 returns the digital data 47-2 of Fig. 34 confirming the call to the SCN boundary 24-1 (step ST61). Here, "CTL-Info-1" in the digital data 47-1 is call control information, and "CTL-Info-2" in the digital data 47-2 is call confirmation information.

Next, when the user of the analog telephone 18-1 dials and enters the telephone number of the analog telephone 18-3 of the communication counterpart, the telephone 18-1 inputs a call setup analog signal to the communication line 55-1. ), And the SCN boundary 23-1 generates the data block 47-3 of FIG. 35 informing the telephone number using the "call setup" analog signal, and transmits it to the H323 terminal 23-1. . Here, the H323 terminal 23-1 is a line identifier indicating a communication line 55-1 by searching for a record in the media router state table 100-1 of FIG. 30, and in this case, the media router state table 100 "55-1" which is the 3rd row record from -1) is detected. Next, the telephone number " 81-47-325-3887 " and the IP address " 20.0.55.1 " of the analog telephone 18-1 described in this record are read. In this example, the specific numerical value of the IP address "A181" of the analog telephone 18-1 is set to "20.0.55.1" (step ST62).

Next, the H323 terminal 23-1 virtually gives an address to the analog telephone 18-1, that is, the sender IP address " A181 ", that is, the address of the domain name server 48-1 in the media router. The IP packet 47-4 in Fig. 36 that stores the new IP address " A481 " and the communication party's telephone number " Tel-18-3 name " is generated and transmitted to the domain name server 48-1 (step ST63). . The domain name server 48-1 examines the contents of the received IP packet 47-4, and then the dedicated domain of the IP telephone network via the communication line 10-1 and the network node device 8-2. The IP packet 47-5 is transmitted to the name server 31-1 (step ST64). The dedicated domain name server 31-1 of the IP telephone network receives an IP packet 47-6 including the IP address "A183" corresponding to 1: 1 with the host name "Tel-18-3 name". When returning to 4848 (step ST65), the domain name server 48-1 returns the IP packet to the H323 terminal 23-1.

Next, the H323 terminal 23-1 generates an IP packet 47-7 to transmit to the H323 terminal 23-2, and via the router 20-3, the network node device 8-2. (Step ST66), the network node device 8-2 transmits this IP packet 47-7 inside the integrated IP transport network 2 of FIG. 3, and the IP packet 47-7 transmits the IP packet network. (4) The network node device 7-2 is reached through the internal routers 19-8, 19-9, 21-2, 19-11, and 19-13. In this way, the network node device 7-2 sends the received IP packet 47-7 to the communication line 10-5, and the H323 terminal 23-2 passes through the router 20-4. To receive the IP packet 47-7. The H323 terminal 23-2 interprets the IP packet 47-7 as a telephone call, and performs the following two processes. The first step is to generate a reply IP packet 47-8 and return it to the router 20-4. The analog telephone 18-3 receives the call packet sound (call tone) by receiving the IP packet 47-7. Ring). The second process is to send the IP packet 47-7 to the analog telephone 18-3 via the SCN boundary 24-2.

Referring to Fig. 7, the IP packet 47-8 generated by the first process passes through the communication line 10-5 (step ST67), the network node device 7-2, and the IP telephone network ( 4) The network node device 8-2 is reached via 4), and the router 20-3, the H323 terminal 23-1, and the SCN boundary 24-1 are connected via the communication line 10-1. Is sent to the analog telephone 18-1. The analog telephone 18-1 interprets it as a communication partner call by receiving the IP packet 47-8.

By the second process, the user of the analog telephone 18-3 hears this ringing tone and lifts the handset of the analog telephone 18-3 (off-hook). In this way, the H323 terminal 23-2 generates the IP packet 47-9 (step ST68), sends the IP packet 47-9 to the router 20-4, and sends the network node apparatus 7 to the router 20-4. -2), the network node device 8-2 is received via the IP telephone network 4, the router 20-3, the H323 terminal 23-1, via the communication line 10-1, It is sent to the analog telephone 18-1 via the SCN boundary 24-1, and the analog telephone 18- as a sound (call setting confirmation sound) informing that the telephone communication partner lifted the handset of the analog telephone 18-3. The user of 1) is notified.

In step ST68, call setting confirmation information, i.e., an IP packet 47-9 indicating the start of telephony communication between the analog telephone 18-1 and the analog telephone 18-3, is transmitted. -2 and 8-2, upon detecting IP packet 47-9, indicate the telephony initiation record, i.e., the initiation of telephony communication between analog telephone 18-1 and analog telephone 18-3. -9) A part of the contents, for example, a source IP address, a destination IP address, a source port number, a destination port number, and a detection time thereof can be held in a billing record file set inside the network node apparatus.

When the user of the analog telephone 18-1 starts a telephony conversation, the voice signal is transmitted to the SCN boundary 24-1 via the communication line 55-1 so that the voice signal is digitally represented. The H323 terminal 23-1 generates an IP packet 47-10 containing the digitized voice, and sends it to the communication line 10-1 (step ST69). The voice packet 47-10 includes the H323 controller 23-1, the router 20-3, the network node device 8-2, the routers 19-8, 19-9, 21-2, 19-11, 19-13), through the network node device 7-2, the router 20-4, and the H323 terminal 23-2, to the analog telephone 18-3. The sound of the user of the analog telephone 18-3 is flowed in the opposite direction to that described above, that is, the H323 control unit 23-2, the router 20-4, the network node device 7-2, and the router 19-13. , Analogue telephones 18-1 via 19-11, 21-2, 19-9, 19-8, network node device 8-2, router 20-3, H323 termination 23-1 ) (Step ST70).

When the user of the analog telephone 18-1 places the handset for terminating the telephone communication, the analog telephone 18-1 sends a call disconnection signal indicating the telephone termination to the communication line 55-1, and the SCN boundary 24 -1) converts the call disconnection signal into a digital data format, and then the H323 terminal 23-1 generates an IP packet 47-12 indicating the end of telephony and sends it to the communication line 10-1. (Step ST71). The IP packet 47-12 includes the H323 controller 23-1, the router 20-3, the network node device 8-2, the routers 19-8, 19-9, 21-2, 19-11, 19-13, the network node device 7-2, the router 20-4, and the H323 terminal 23-2, and are sent to the analog telephone 18-3. When the user of the analog telephone 18-3 knows that the telephone communication has ended and releases the handset, the H323 terminal 23-2 generates and sends an IP packet 47-13 to flow in the opposite direction to the above-mentioned, That is, the H323 control unit 23-2, the router 20-4, the network node device 7-2, the routers 19-13, 19-11, 21-2, 19-9, 19-8, and network nodes It is sent to the apparatus 8-2, the router 20-3, and the H323 terminal portion 23-1 (step ST72).

In step ST72, call disconnection confirmation information, that is, an IP packet 47-13 indicating the end of telephony communication between the analog telephone 18-1 and the analog telephone 18-3 is transmitted, and the network node apparatus 8 -2 and 7-2, when detecting the IP packet 47-13, indicate that the telephony end record, i.e., the telephony end between the analog phone 18-1 and the analog phone 18-3, is completed. A part of the contents, for example, the source IP address, the destination IP address, the source port number, the destination port number, and the time of detection thereof can be kept in the billing record file inside the network node apparatus.

According to the above procedure, the analog telephone 18-1 and the analog telephone 18-3 can perform telephone communication by sending and receiving IP packets.

In the above-described communication procedure, except for the domain name server 48-1 in the media router from the media router 14-1, the above steps ST63 to ST65 may be replaced by steps ST63x and ST65x described below. That is, the H323 end portion 23-1 is the address of the analog telephone 18-1, that is, the source IP address "A181", the address of the dedicated domain name server 31-1 of the IP telephone network, that is, the destination IP address ". A311 ", and the IP packet 47-14 which stored the communication partner telephone number" Tel-18-3 name "is used for IP telephone via the communication line 10-1 and the network node apparatus 8-2 only. The data is sent to the domain name server 31-1 (step ST63x). The domain name server 31-1 sends the H323 terminal 23-1 an IP packet 47-15 including the IP address " A183 " that corresponds 1: 1 to the correspondent telephone number " Tel-18-3 name. &Quot; ) (Step ST65x).

In the steps ST63 to ST65 or the steps ST63x and ST65x described above, the network node device 8-2 transmits the source address included in the IP packet 47-5 received via the communication line 10-1. By checking whether or not the combination of A481 "and the communication line identification symbol" Line-10-1 "is registered in the address management table 44-1 (FIG. 8), or the network node device 8-2 checks the communication line 10 The combination of the source address " A181 " and the communication line identification symbol " Line-10-1 " included in the IP packet 47-14 received via -1) is stored in the address management table 44-1 (FIG. 8). By checking whether it is registered, it is confirmed that the analog telephone 18-1 is allowed to communicate via the network node device 8-2 from the communication line 10-1, that is, the communication permission is registered. do.

<< IP Data Service Operation Management Server >>

The IP data service operation management server 35-1 under management of the communication company X periodically or occasionally transmits and receives an inquiry IP packet with the network node devices 8-2 and 8-4, and thereby the step. In ST11, an IP terminal communication record created by the network node device is obtained. The IP data service operation management server 35-1 is dedicated to internal resources of the IP data network managed by the communication company X, for example, routers 19-1, 19-2, 19-3, and IP data network. The communication line between the domain name servers 30-1 and 30-2 and the router is checked whether or not it is normal by means of sending and receiving ICMP packets (fault management), and the IP packets in the IP data network By monitoring whether the congestion is excessive or not (communication quality control), the IP data network of the communication company X is collectively managed.

Similarly, the IP data service operation management server 35-2 under the management of the communication company Y records the communication between the IP terminals by sending and receiving an inquiry IP packet with the network node devices 7-2 and 7-4 periodically or occasionally. And manages the failure management and communication quality of the IP data network of the communication company Y collectively. In addition, the IP data service operation management server 35-1 and 35-2 may be divided into an IP data service server for exclusively managing IP data services and an IP data network operation management server for exclusively managing resources of the IP data network. .

<< IP telephone service operation management server >>

The IP telephone service operation management server 36-1 under the management of the communication company X periodically transmits or receives the inquiry IP packet to the network node device 8-2 or 8-4 or the like periodically or occasionally, thereby making the telephone communication start record and the telephone call. Acquire a communication end record. In addition, communication lines between internal resources of the IP telephone network managed by the communication company X, for example, routers 19-8, 19-9, 19-10, dedicated domain name servers 31-1 of the IP telephone network, and routers. By checking means such as sending and receiving ICMP packets (failure management), and monitoring whether or not the congestion of IP packets in the IP telephone network is excessive (communication quality management). Manage and manage IP telephone network at once.

Similarly, the telephone service operation management server 36-2 under the management of the telecommunication company Y periodically transmits or receives the inquiry IP packet to the network node devices 7-2 and 7-4 or the like periodically, and thereby, the telephone communication initiation record. Acquire the telephony termination record to collectively manage the failure management and the communication quality of the IP telephone network of the communication company Y.

It is also possible to omit the telephone communication start record at step ST28 and step ST68 and the telephone communication end record at step ST32 and step ST72 during the procedure. In this case, the telephone communication start record by communication company X or communication company Y is omitted. The acquisition of the telephone and telephony termination record can be omitted.

The IP telephone service operation management servers 36-1 and 36-2 may be divided into an IP telephone service server for exclusively managing IP telephone service and an IP telephone network operation management server for exclusively managing resources of the IP telephone network.

<< IP voice video service operation management server >>

The IP voice video service operation management server 37-1 under the management of the communication company X periodically or occasionally transmits and receives an inquiry IP packet with the network node devices 8-2 and 8-4, thereby recording the voice video communication start. And audio image communication end record. In addition, internal resources of the IP voice video network managed by the communication company X, for example, routers 19-14 and 19-15, dedicated domain name servers 32-1 of the IP telephone network, communication lines between routers, and the like, may be used. The IP of the communication company X is checked by checking whether the ICMP packet is normal or not (failure management), and monitoring whether or not the congestion of the IP packet in the IP audio network is excessive (communication quality management). Manage and manage voice video network at once.

Similarly, the IP voice video service operation management server 37-2 under the management of the communication company Y periodically or occasionally transmits and receives an inquiry IP packet to or from the network node device 7-2 or 7-4, thereby transmitting the voice video communication. The start record and the end of the audio image communication are acquired to collectively manage and manage the failure management and the communication quality of the audio image network of the communication company Y. In addition, IP voice video service operation management servers 37-1 and 37-2 are IP voice video service servers for exclusively managing IP voice video services, and IP voice video network operation management servers for exclusively managing resources of voice video network. It can also be divided into

<< Best effort service operation management server >>

 The best effort service operation management server 38-1 under the management of the telecommunication company X collectively manages the failure management and the communication quality of the best effort network of the telecommunication company X. Similarly, the best effort service operation management server 38-2 under the management of the telecommunication company Y collectively manages the failure management and the communication quality of the best effort network of the telecommunication company Y. In addition, the best effort service operation management servers 38-1 and 38-2 respectively manage the best effort service server for managing best effort services and the best effort service network for managing resources of the best effort service network. It can also be divided into management servers.

In the above description, there are parts in which the element names of the embodiments are given, for example, "H323 termination", "H323 gateway", and the like, but are not meant to comply with the ITU-H323 recommendation, but indicate that they have related communication functions.

As shown in FIG. 48, the media router operator 102 exchanges information with the RAS management program 101-1 inside the RAS mechanism 49-1 via the operation input / output unit 51-1, or manages the RAS. By rewriting the RAS table in the program, the registration and authentication of the terminal and the internal state of the media router 14-1 are managed.

As shown in Fig. 49, the terminal operator 103 operates the non-independent IP telephone 13-1, and this operation information is stored in the H323 terminal program 105-2, and then in the communication line 53-1. By exchanging information with the interface 105-1 of the RAS management program inside the RAS mechanism 49-1 and the AP layer 101-2 of the RAS management program via the virtually existing three-layer communication path 106, The RAS table in the RAS management program is rewritten to manage the registration and authentication of the terminal and the internal state of the media router 14-1.

As shown in Fig. 50, the telephone operator 104 operates the analog telephone 18-1, and this operation information is stored in the telephone operation program 106-2 in the SCN boundary 24-1, and then RAS. By exchanging information with the TCP / IP interface 106-1 of the RAS management program inside the mechanism 49-1 and the AP layer 101-3 of the RAS management program, and by rewriting the RAS table in the RAS management program, It manages the registration and authentication of the terminal and the internal state of the media router 14-1.

In the embodiment of Fig. 3, the routers 21-1 to 21-5 may be excluded, except for all the internal elements of the range 6-2 of the IP transport network managed by the communication company Y. In this case, the inside of the integrated IP transport network 2 includes the range 6-1 of the IP transport network managed and managed by the communication company X, and the network node devices 7-1 to 7-4 and 8-1 to 8-. 4) and gateways 9-1 and 9-2. In the case of IP data communication, information is transmitted from the network node device 8-2 to the network node device 7-2 via the router 19-1 and the router 19-3, for example. In the case of communication, information is transmitted from the network node device 8-2 to the network node device 7-2 via routers 19-8 and 19-9, for example.

2. Second embodiment using a gateway:

<< Communication between analog phones via gateway >>

The media routers 14-1 and 14-2 of Figs. 6 and 7 have almost the same internal configuration and function as the gateway 9-1 of Fig. 51 and the gateway 9-2 of Fig. 52, and differ in that While the media routers 14-1 and 14-2 are outside of the integrated IP transport network 2, the gateways 9-1 and 9-2 are inside the integrated IP transport network 2, and the gateway ( Since the charging units 72-1 and 72-2 are provided inside the 9-1 and 9-2, the media routers 14-1 and 14-2 and the gateways 9-1 and 9-2, respectively. The inside of is composed of common internal element blocks such as the SCN boundary, the H323 termination, the connection control and the router. Reference numeral 79-1 denotes a RAS mechanism of the gateway 9-1, reference numeral 80-1 denotes an information processing mechanism of the gateway 9-1, and reference numeral 81-1 denotes an operation input / output of the gateway 9-1. It is wealth. Media routers and gateways have almost the same functionality, except that the processing of billing is different.

The IP terminal 11-6 or the non-independent IP telephone 13-3 is connected to the gateway 9-1 via the communication line, and the IP terminal 11-10 is passed through the communication line to the gateway 9-2. Or non-independent IP audio and video device 16-4 is connected to each other via a gateway 9-1, an integrated IP transport network 2, and a gateway 9-2 to enable communication between terminals via a media router. For example, the terminal-to-terminal communication between the IP terminal 11-6 and the IP terminal 11-10 shown in FIG. 3, or the terminal between the non-independent IP telephone 13-3 and the non-independent IP telephone 13-4. The inter-communication communication or the inter-terminal communication between the non-independent IP audio image device 16-1 and the non-independent IP audio image device 16-4 is possible.

Hereinafter, with reference to FIGS. 51-68, between the analog telephone 18-5 and the analog telephone 18-6 which are made via the gateway 9-1, the integrated IP transport network 2, and the gateway 9-2. Describes the communication sequence.

When the handset of the analog telephone 18-5 is lifted, a call signal is routed inside the gateway 9-1 via the telephone line 17-3, the public switched telephone network 26-1, and the telephone line 17-1. Incoming to the SCN boundary 77-1 (step S60 in FIG. 51), the SCN boundary 77-1 sends a call confirmation signal to the analog telephone 18-5 via the public switched telephone network 26-1. It returns (step S61). Next, when the user of the analog telephone 18-5 dials and enters the telephone number "Tel-18-6 name" of the communication counterpart telephone 18-6, the analog telephone 18-5 receives a call setup signal. When sending to the communication line 17-3, the call setting signal reaches the SCN boundary 77-1 through the public switched telephone network 26-1 and the telephone line 17-1 (step S62). The data block 48-1 shown in FIG. 53 in which the setting signal is digitized is transmitted to the H323 terminal 76-1 (step S62x), and the H323 terminal 76-1 is the gateway state table 100 of FIG. -2) The internal record is searched to detect a line identifier indicating the communication line 17-1, in this case "17-1" which is the first row record from the top of the gateway state table 100-2.

Next, the telephone number " 81-3-9876-5432 " and the IP address " 100.101.102.103 " of the analog telephone 18-5 described in this record are read. In addition, the H323 terminal 76-1 has an address of the analog telephone 18-5, that is, a source IP address "A185", an address of a domain name server 78-1 in the gateway, that is, a destination IP address "A781". The IP packet 48-2 storing the communication counterpart phone number "Tel-18-6 name" is generated and transmitted to the domain name server 78-1 (step S63). The domain name server 78-1 examines the contents of the received IP packet 48-2 and passes the network packet to the dedicated domain name server 31-1 of the IP telephone network via the network node device 8-4. 48-3) is transmitted (step S64). The dedicated domain name server 31-1 of the IP telephone network domains an IP packet 48-4 including the IP address " A186 " corresponding to 1: 1 to the communication counterpart telephone number " Tel-18-6 name ". When returning to the name server 78-1 (step S65), the domain name server 78-1 returns the IP packet to the H323 terminal 76-1.

Next, the H323 terminal 76-1 generates an IP packet 48-5 and sends it to the network node device 8-4 (step S66), and the network node device 8-4 sends this IP packet. (47-5) is transmitted inside the integrated IP transport network 2 of FIG. 3, the IP packet 48-5 is routed to the routers 19-8, 19-9, 21-2, 19 inside the IP telephone network 4. -11, 19-13 to reach the network node device 7-4. In this way, the network node device 7-4 sends the received IP packet 48-5 to the SCN boundary 77-2 via the router 74-2 and the H323 terminal 76-2. . The SCN boundary 77-2 interprets the IP packet 48-5 as a telephone call to the analog telephone 18-6, and transmits a call signal to the telephone line 17-2 (step S66 x). When the call confirmation signal is received from the public switched telephone network 26-2 (step S66y), the following two processes are performed. The first step is to generate a reply IP packet 48-6 and return it to the router 74-2. The second step is to send a call setup signal through the line 17-2 to the public switched telephone network 26-2. Will be sent out.

The IP packet 48-6 generated by the first process is received by the network node device 8-4 via the network node device 7-4 (step S67) and via the IP telephone network 4; Is sent to the H323 terminal portion 76-1 inside the gateway 9-1. Next, the H323 terminal 76-1 understands that the received IP packet 48-6 is calling the telephone (analog telephone 18-6) of the communication partner, and the data block 48-7 means a ring tone. Is sent to the SCN boundary 77-1. In this way, the SCN boundary 77-1 transmits a ring tone to the communication line 17-1, and the ring tone is transmitted through the public switched telephone network 26-1 and the communication line 17-3. When -5) is reached, the analog telephone 18-5 interprets that the analog telephone 18-6 of the communication partner is calling.

By the second process, the analog telephone 18-6 receives the call setup signal (step S67x) and sounds a ring tone. When the user of the analog telephone 18-6 hears this ringing tone and picks up the handset of the analog telephone 18-6, a call setup confirmation signal is sent from the analog telephone 18-6, and the line 17-4 and public switching are performed. The call arrives at the SCN boundary 77-2 via the telephone network 26-2 and the line 17-2. When the SCN boundary 77-2 forwards the response reception to the H323 termination 76-2 (step S67y), the H323 termination 76-2 generates an IP packet 48-8 to generate the H323 termination ( It sends out toward 76-1) (step S68). In this way, the IP packet 48-8 reaches the network node device 8-4 via the network node device 7-4 and the IP telephone network 4, and the router (inside the gateway 9-1) ( The terminal reaches the H323 terminal 76-1 through 74-1).

The H323 end portion 76-1 understands that the received IP packet 48-8 is a response (that is, the user of the analog telephone 18-6 lifts the handset), and means to confirm call setup. The data block 48-9 is sent to the SCN boundary 77-1. In this way, the SCN boundary 77-1 sends a call setup confirmation signal to the communication line 17-1, and transmits the analog telephone (via the public switched telephone network 26-1 and the communication line 17-3). 18-5).

In step S68, the response information, i.e., the IP packet 48-9 indicating the start of the telephone communication between the analog telephone 18-5 and the analog telephone 18-6, is transmitted, and the network node apparatus 7-4. Or 8-4), upon detecting the IP packet 48-9, indicates the telephony initiation record, i.e., the fact that the telephony commencement between the analog telephone 18-5 and the analog telephone 18-6, together with the time, is performed. It can be kept in a billing log file that is set up inside the device.

When the user of the analog telephone 18-1 starts a telephony conversation, the voice signal is sent to the SCN via the communication line 17-3, the public switched telephone network 26-1, and the communication line 17-1. The voice signal is transmitted to the boundary 77-1, the digital signal is digitally represented, and the H323 terminal 76-1 then generates an IP packet 48-10 including the digitized voice. Voice packet 48-10, which is an IP packet, includes router 74-1, network node device 8-4, routers 19-8, 19-9, 21-2, 19-11, 19-13, Network node device 7-4, H323 end portion 76-2, SCN boundary 77-2, communication line 17-2, public switched telephone network 26-2, and communication line 17-4 Is sent to the analog telephone 18-6 (step S69). The voice of the user of the analog telephone 18-6 is an IP packet 48-11, which flows in the opposite direction to that described above, that is, the SCN boundary 77-2, the H323 control unit 76-2, and the network node device 7 4), H323 terminations (76-) inside routers (19-13, 19-11, 21-2, 19-9, 19-8), network node devices (8-4), gateways (9-1) 1) It is sent to the analog telephone 18-5 via SCN boundary 77-1, communication line 17-1, etc. (step S70).

When the user of the analog telephone 18-5 puts the handset on for termination of telephony, the analog telephone 18-5 sends a call disconnection signal indicating the telephone termination to the communication line 17-3, and the SCN boundary 77 -1) converts the call disconnection signal into a digital data format, and then the H323 terminal 76-1 generates an IP packet 48-12 indicating the end of the telephony and sends it to the router 74-1. (Step S71), IP packet 48-12 is network node device 8-4, routers 19-8, 19-9, 21-2, 19-11, 19-13, network node device 7 -4), the H323 terminal 76-2 and the SCN terminal 77-2 are sent to the analog telephone 18-6. When the user of the analog telephone 18-6 knows that the telephone communication has been terminated and releases the handset, the SCN boundary 77-2 understands the call disconnection confirmation (i.e., terminates the telephone communication) and at the same time the public switched telephone network 26- 2) informs the user of the " charge of public switched telephone network " required for telephony communication between analog telephone 18-5 and analog telephone 18-6. For example, when the communication line 17-2 is an ISDN line, billing information is notified at the end of the telephony communication.

The SCN boundary 77-2 notifies the H323 terminal 76-2 of the obtained fee for using the public switched telephone network as a charging fee. The H323 terminal 76-2 knows the call release confirmation and the charged fee, and can perform the following two processes. The H323 terminal 76-2 generates the IP packet 48-13 as the first process and sends the packet to the router 74-2. In this way, the flow in the opposite direction to the above, that is, the network node device 7-4, the routers 19-13, 19-11, 21-2, 19-9, 19-8, and the network node device 8-4 And the H323 terminal 76-1 (step S72). In addition, the H323 terminal 76-2 transmits data operating in the gateway 9-2 to the data block 48-14, which includes the charging fee information obtained according to the procedure as the second process. The billing unit 72-2 is notified using the function. The charging unit 72-2 may hold charging information using the public switched telephone network 26-2 in the telephone communication between the obtained analog telephone 18-5 and the analog telephone 18-6. The SCN boundary 77-2 notifies the H323 terminal 76-2 of the obtained public switched telephone network as a fee. The H323 termination unit 76-2 knows the call release confirmation and the charge, and can carry out the following two procedures. The H323 terminal 76-2 generates the IP packet 48-13 as the first process and sends the packet to the router 74-2. In this way, the flow in the opposite direction to the above, that is, the network node device 7-4, the routers 19-13, 19-11, 21-2, 19-9, 19-8, and the network node device 8- 4) and H323 terminal portion 76-1 (step S72). In addition, the H323 terminal 76-2 transmits data operating in the gateway 9-2 to the data block 48-14, which includes the charging fee information obtained according to the procedure as the second process. The billing unit 72-2 is notified using the function. The charging unit 72-2 may hold charging information using the public switched telephone network 26-2 in the telephone communication between the obtained analog telephone 18-5 and the analog telephone 18-6. have.

According to the above procedure, the analog telephone 18-5 and the analog telephone 18-6 can perform telephone communication by sending and receiving IP packets.

Step S72 is a process in which call disconnection confirmation information, that is, an IP packet 48-13 indicating the end of telephony communication between the analog telephone 18-5 and the analog telephone 18-6, is transmitted, and the network node apparatus 8 -4 and 7-4, together with the time, when the IP packet 48-13 is detected, the telephony end record, i.e., the telephony end between analog phone 18-5 and analog phone 18-6. It can be kept in a billing log file that is set inside the network node device.

The IP telephone service operation management server 36-1 under the management of the communication company X periodically transmits or receives the inquiry IP packet with the network node device 8-4 periodically or from time to time so as to record the telephony start record and the telephony end record. Acquire. The IP telephone service operation management server 36-1 also obtains the charging information by sending and receiving an inquiry IP packet with the charging unit 72-1. Similarly, IP telephone service operation management server 36-2 under the management of telecommunication company Y acquires the telephony initiation record and the telephony end record by sending or receiving an inquiry IP packet with network node device 724 periodically or occasionally. . The IP telephone service operation management server 36-2 also acquires the charging information by sending and receiving an inquiry IP packet with the charging unit 72-2.

In the above-described communication procedure, except for the domain name server 78-1 from the gateway 9-1, the above steps S63 to S65 may be replaced by steps S63x and S65x described below. That is, the H323 terminal 76-1 is the address of the analog telephone 18-5, that is, the source IP address "A185", the address of the dedicated domain name server 31-1 of the IP telephone network, that is, the destination IP address ". A31I "and the IP packet 48-15 which stored the communication party telephone number" Tel-18-6 name "are transmitted to the domain name server 31-1 via the network node apparatus 8-4 (step S31). S63x). The dedicated domain name server 31-1 of the IP telephone network H323 terminates the IP packet 48-16 including the IP address " A186 " corresponding to 1: 1 to the correspondent telephone number " Tel-18-6 name. &Quot; It returns to part 76-1 (step S65x).

In the process of steps S63 to S65 or steps S63x and S65x described above, the network node device 8-4 performs the domain name server 78 in the gateway via the communication line 17-1 and the H323 end portion 76-1. The combination of the sender address "A781" and the communication line identifier "Line-17-1" included in the IP packet 48-3 generated in -1) is registered in the address management table 44-2 (FIG. 69). Or the network node apparatus 8-4 checks the source address " A185 " and the communication line identification symbol " Line- " included in the IP packet 48-15 generated at the H323 terminal 76-1. By checking whether or not the combination of 17-1 "is registered in the address management table 44-2 (FIG. 69), the analog telephone 18-5 is connected to the network node device 8-4 from the communication line 17-1. Communication via is permitted. That is, it is confirmed that communication permission is registered.

<< telephone service operation management server >>

The IP telephone service operation management server 36-1 under the management of the communication company X periodically transmits or receives the inquiry IP packet with the network node devices 8-2 and 8-4 periodically or at any time, thereby making the telephone communication start record and telephony communication possible. Get the end record. In addition, ICMP packets are stored in internal resources of the IP telephone network managed by communication company X, for example, routers 19-8, 19-9, 19-10, domain name servers 31-1, and communication lines between routers. The IP telephone network of the telecommunication company X is collectively checked by checking whether or not it is normal by means of sending and receiving data (fault management), and monitoring whether or not the congestion of IP packets in the IP telephone network is excessive (communication quality management). Operation management.

Similarly, the IP telephone service operation management server 36-2 under the management of the telecommunication company Y periodically transmits or receives the inquiry IP packet to the network node device 7-2 or 7-4 or the like periodically, and thereby, records and starts the telephone communication start. Acquire the telephony termination record to collectively manage the failure management and the communication quality of the IP telephone network of the communication company Y.

In the above process, the telephone communication start record in step S68 and the telephone communication end record in step S72 may be omitted, in which case the telephone communication start record by the communication company X or the communication company Y and the telephone communication end record may be omitted. Acquisition may be omitted. The IP telephone service operation management servers 36-1 and 36-2 may be divided into an IP telephone service server for exclusively managing IP telephone service and an IP telephone network operation management server for exclusively managing resources of the IP telephone network.

3. Third Embodiment Using Gateway:

With reference to FIG. 71, the 3rd Embodiment which performs communication connection between terminals using an IP transmission network by using the media router which concerns on this invention inside a CATV communication network is demonstrated.

The media router 115 is located inside the CATV gateway 113-2 inside the CATV network 113-1 and is connected to the network node device 111 inside the integrated IP transmission network 110 through the communication line 112. In addition, the media router 115 passes through any one of the CATV line interface 114, the CATV lines 119-1 to 119-4, and the IP terminals 116-1 to 116-3, the analog telephone 117, The non-independent IP telephone 118-1 and the non-independent IP audio image device 118-2 are connected. The CATV lines 119-1 to 119-4 include a communication lower layer (communication physical layer and data link layer) specific to the CATV line, and have a function of transmitting an IP packet in a communication network. The IP packet transmitted from the IP terminal 116-1 enters the CATV line interface 114 via the CATV line 119-1, where the IP packet is drawn out and sent to the media router 115. The media router 115 is configured in the same manner as the media router 14-1 in FIG. 6 and includes the same function as the media router 14-1, for example, a domain name server. For this reason, the media router 115 can convert the IP packet containing the call control data into DNS inquiry response format data and send it to the communication line 112, and also the analog telephone 117 or the non-standalone IP telephone. 118-1, the IP packet inputted from the non-independent IP voice imager 118-2 through the CATV lines 119-2 to 119-4 and the CATV line interface 114 via the media router 115. IP packet transmitted to the communication line 112 and vice versa, that is, the IP packet transmitted from the network node device 111 via the communication line 112 via the media router 115 and passes through the CATV line interface 114. Next, the IP terminal 116-1, the analog telephone 117, the non-independent IP telephone 118-1, and the non-independent IP voice image device (A) through any one of the CATV lines 119-1 to 119-4. 118-2).

According to the principle described above, the IP terminal 116-1, the analog telephone 117, the non-independent IP telephone 118-1, and the non-independent IP audio image apparatus 118-2 in the CATV network 113-1. By way of the integrated IP transport network 110, as described in other embodiments, other various terminals connected to the integrated IP transport network 110 using a domain name server in the integrated IP transport network, that is, an IP terminal or an analog telephone. Communication between terminals, such as an IP telephone and an IP audio visual apparatus, is possible.

The IP terminal 116-1 presents the host name of the communication counterpart IP terminal to the domain name server in the integrated IP transmission network 110 via the CATV line 119-1 and the CATV gateway 113-2. By acquiring the IP address of the IP terminal and then transmitting data from the IP terminal 116-1 to the counterpart IP terminal, inter-terminal communication for transmitting and receiving data can be performed. Similarly, the analog telephone 117 communicates to the domain name server in the integrated IP transport network 110 via the CATV line 119-2 and the CATV gateway 113-2, that is, the host name of the counterpart analog telephone, that is, the counterpart telephone. The telephone number can be obtained by obtaining the IP address of the counterpart phone, and then transmitting and receiving voice data with the counterpart analog phone from the analog phone 117. FIG. Similarly, the non-independent IP phone 118-1 communicates with the domain name server inside the integrated IP transport network 110 via the CATV line 119-3 and the CATV gateway 113-2, and the host name of the counterpart analog phone, That is, the telephone communication can be performed by presenting the telephone number of the counterpart phone to obtain the IP address of the counterpart phone, and then transmitting and receiving voice data with the counterpart analog phone from the non-standalone phone 118-1.

4. Fourth embodiment using a gateway having a wireless interface:

Referring to Fig. 72, a fourth embodiment in which a terminal accommodating wireless device is combined with a gateway according to the present invention and a communication connection between terminals using an IP transmission network is described.

Reference numeral 120 denotes an integrated IP transmission network, reference numeral 121 denotes a network node device, reference numeral 122 denotes a gateway, reference numeral 123 denotes a radio transceiver, reference numeral 124-1 denotes an air interface converter, reference numeral 124-2 denotes a communication line, Reference numeral 125 denotes a wireless communication path, reference numeral 126 denotes a terminal accommodating wireless device, reference numeral 127 denotes a wireless transceiver, reference numeral 128-1 denotes an IP terminal, reference numeral 128-2 denotes a non-standalone IP telephone, and reference 128-3 Is a non-independent IP audio image device, and reference numerals 129-1 to 129-3 are air interface converters. The gateway 122 includes the same functions as the gateway 9-1 of FIG. 51, and when a terminal such as an IP terminal, an H323 terminal, or an analog telephone is connected via the communication line 124-2, communication between the terminals is performed. Available for For this reason, communication between terminals can be performed by connecting an IP terminal, an IP telephone, and an IP audio visual apparatus by the communication line 124-2.

The data of the DNS inquiry response format or the text data transmitted / received from the IP terminal 128-1 is converted into the input data format of the wireless transceiver by the wireless interface converter 129-1 and input to the wireless transceiver 127. Is transmitted to the wireless transmission / reception unit 123 via the wireless communication path 125 and converted into a data format of an IP packet which can be input to the gateway by the wireless interface conversion unit 124-1, and via the communication line 124-2. Is sent to the gateway 122. The call control data of the telephone transmitted from the non-independent IP telephone 128-2 or the digitally expressed voice data transmitted / received are converted into the input data format of the radio transceiver from the radio interface converter 129-2 and the radio transceiver 127 Data of the IP packet inputted to the gateway via the radio communication path 125, the radio transceiver 123, the radio interface converter 124-1, and the communication line 124-2, respectively. The format is sent to the gateway 122. The call control data of the IP voice image apparatus 128-3 transmitted from the non-independent IP voice image apparatus 128-3, or the digitally expressed voice and moving image data transmitted / received are converted into the input data format of the wireless transceiver unit by the air interface converter 129-3. The signal is converted and input to the radio transmitter / receiver 127. Then, the gateway is connected via the radio communication path 125, the radio transceiver 123, the radio interface converter 124-1, and the communication line 124-2. The data format of an IP packet that can be input to the data is sent to the gateway 122. In addition, data packets in the opposite direction, for example, IP packets for IP phones, are transmitted from the network node apparatus 121 to the gateway 122, the communication line 124-2, the air interface converter 124-1, and the radio transceiver. 123, the radio communication path 125, the radio transceiver 127, and the radio interface converter 129-2 are sent to the non-independent IP phone 128-2.

In addition, the IP terminal 128-1, the non-independent IP telephone 128-2, and the non-independent IP voice imager 128-3 connected to the terminal accommodating wireless device 126 pass through the integrated IP transmission network 120. Therefore, communication between the terminals and other terminals connected to the integrated IP transmission network 120, that is, an IP terminal, an analog telephone, an IP telephone, or an IP voice video apparatus, is possible.

5. Fifth Embodiment of Different Gateway Structures:

This embodiment is another embodiment in which the structure of the gateway 9-1 shown in FIG. 51 of the second embodiment is different, and will be described with reference to FIG. 73.

Reference numeral 9-5 denotes a gateway, reference numeral 74-5 denotes a router, reference numeral 78-5 denotes a domain name server, reference numeral 79-5 denotes registration and authentication of a terminal to the gateway 9-5, and a gateway 9 -5) RAS mechanism to manage internal state (e.g. communication state, suspended state). Here, "terminal registration" refers to connecting the terminal to the gateway, and "authentication" refers to confirming whether or not the terminal can be regularly used according to the access permission condition of the terminal. Reference numeral 80-5 denotes an information processing mechanism responsible for processing information inside the gateway 9-5, reference numeral 81-5 denotes an operation input / output unit of the gateway 9-5, and reference numeral 72-5 applies a fee. It is wealth. Reference numeral 82-3 denotes an H323 communication sequence gateway unit (H323-GW), reference numeral 75-3 denotes an H323 connection controller, reference numeral 76-3 denotes an H323 termination portion, reference numeral 77-3 denotes an SCN boundary, and 82-4 is a gateway for SIP communication sequence (SIP-GW), 75-4 is a SIP access controller, 76-4 is a SIP terminating end, and 77-4 is an SCN boundary. Reference numeral 52-3 denotes an IP communication line to which an IP terminal can be connected, reference numeral 53-3 denotes a communication line to which an IP telephone in an H323 communication sequence can be connected, and reference numeral 53-4 denotes an IP telephone line in an SIP communication sequence. Possible communication lines, and reference numerals 17-3 and 17-4 are communication lines following the public switched telephone network, respectively.

The gateway 9-5 in Fig. 73 is replaceable with the gateway 9-1 in Fig. 51 of the second embodiment, and the router 74-5 is the router 74-1 and the domain name server 78-5. ) Is the domain name server 78-1, the RAS mechanism 79-5 is the RAS mechanism 79-1, the information processing mechanism 80-5 is the information processing mechanism 80-1, and operation input / output. The unit 81-5 is an operation input / output unit 81-1, the charge charging unit 72-5 is a charge charging unit 72-1, and the H323 connection control unit 75-3 is an H323 connection control unit 75. -1), the H323 termination portion 76-3 can be replaced with the H323 termination portion 76-1, and the SCN boundary portion 77-3 can be replaced with the functions of the SCN boundary portion 77-1. Thus, after replacing the gateway 9-5 of FIG. 73 with the gateway 9-1 of FIG. 51, the IP terminal is connected to the IP communication line 52-3, and the communication line 53- 3) is connected to an IP telephone in the H323 communication sequence, an analog telephone is connected to the communication line 17-3, and is connected to the integrated IP transmission network 2 via the gateway 9-5. Communication can be performed by connecting to the terminals 11-10 and 18-6 of 52 and the like. Reference numeral 82-3 of the H323-GW denotes "the gateway communication interface function unit for the H323 communication sequence".

Similarly, the SIP-GW 82-4 is a gateway communication interface function unit for the SIP communication sequence, passes through the communication line 53-4 from the IP telephone in the SIP communication sequence connected to the communication line 53-4, and performs the SIP. By passing through the SIP connection control unit 75-4 and the router 74-5 which perform terminal connection according to the SIP communication sequence via the SIP terminal 76-4 which operates a terminal according to a communication order, FIG. Communication can be performed by connecting to a telephone 18-6 or the like. Further, communication can be performed by connecting to the telephone 18-6 or the like via the SCN boundary 77-4 from the telephone connected to the communication line 17-4.

The H323-GW 82-3 and the SIP-GW 82-4 provide communication line interfaces corresponding to two communication sequences. When the communication means is newly developed later, a new gateway for communication means may be added at the positions of the gateways 82-3 and 82-4. By including a plurality of gateway communication interface functional units for each communication order, it is possible to cope with telephone connection control of various communication orders.

6. Sixth embodiment using telephone management server:

In Fig. 74, reference numeral 201 denotes an integrated IP communication network, reference numeral 202 denotes an IP data network, reference numeral 203 denotes an IP telephone network, reference numeral 204 denotes a voice video network, and reference numeral 206-1 denotes an integrated management managed by the telecommunication company 1. The range of the IP network, reference numeral 206-2 is the range of the integrated IP network managed by the telecommunication company 2. With reference to FIG. 74 and FIG. 75, preparation from telephone communication is demonstrated. Network node device 209-2 from analog telephone 213-5 via media router 212-1, communication line 210-1, network node device 208-1, and IP telephone network 203. The communication connection control method between terminals for carrying out telephone communication to the communication line 210-5, the media router 212-2 and the analog telephone 214-4 will be described. Reference numerals 219-1 to 219-10 and 221-1 denote routers, and various servers are arranged in the integrated IP communication network 201, and each server is assigned an IP address. As shown in Fig. 74, various servers, routers, and node devices are each connected by an IP communication line, and IP packets can be transmitted and received and data exchanged by the respective IP communication means. Reference numerals 209-1 and 209-2 are telephone gateways, and for example, telephone communication can be performed from the analog telephone 209-4 via the public switched telephone network 209-3, which in another embodiment Explaining. In addition, the telephone management servers 313-5 and 314-5 are roughly equivalent to the connection servers 1-5 and 1-6 of FIG. The gateways 209-1 and 209-2 correspond roughly to the relay connection servers 1-7 in FIG. 1, and the functions of these gateways are described in other embodiments.

Reference numerals 213-1 and 214-1 denote PBXs that accommodate analog telephones, reference numerals 213-2 to 213-6 and 214-2 to 214-6 are analog telephones. Telephones 213-2 and 213-3 are connected to PBX 213-1, telephones 214-2 and 214-3 are connected to PBX 214-1, and telephones 213-4 to 213-6. Is connected to the media router 212-1, and the telephones 214-4 to 214-6 are connected to the media router 212-2.

The media router 212-1 is assigned an IP address "EA01", and the media router 212-2 is assigned an IP address "EA02". The telephones 213-4 to 213-6 are assigned a representative telephone number "Tel-No-I", and the telephones 214-4 to 214-6 are assigned a representative telephone number "Tel-No-2". -2, 213-3, 214-2, and 214-3 are assigned the extension telephone numbers "2132", "2133", "2142", and "2143", respectively. The extension telephones 2131-2 and 213-3 do not communicate with the telephones of the IP telephone network 203 side from the media router 212-1, and the extension telephones 214-2 and 214-3 likewise use the media router ( 212-2) does not communicate with the telephone of the IP telephone network 203 side.

<< preparation of telephone communication >>

The user 227-1 wishing to use the IP telephone requests the use of the IP telephone service to the IP telephone receiver 228-1 belonging to the telecommunication company 1 (step P100 in Fig. 75), and the IP telephone receiver 228-1 is the IP telephone. User's name and address, the payment method of the communication fee, and the user's telephone number "Tel-No-1" obtained from the user 227-1, and the external IP address "EA01" assigned to the media router 212-1. &Quot; L210-1 " of communication line 210-1 used by user to connect media router 212-1, and network node device 208- to which this communication line 210-1 is connected. The network node device identification code "NN-208-1" of 1) is notified to the user service server X313-6 (step P101). Here, the user 227-1 presents the IP address "EA01" to the IP telephone receiver 228-1.

The user sets the media router 212-1 with the IP address " EA01 " used in correspondence with the user telephone number " Tel-No-1 ". Next, the user service server 313-6 gives the user 227-1 the user identification symbol "UID-1" for identifying the received telephone user, and assigns "UID-1" to the external IP address "EA01". In response to " internal IP address " IA01 " for the user 227-1, and the user name and address obtained by the reception, the payment method of the communication fee, the user telephone number " Tel-No-1 ", the external IP address " It holds | maintains in the database of a user service server with information, such as EA01 "(step P102). Since the telephone 213-5 uses the external IP address "EA01" corresponding to the telephone number "Tel-No-1", the external IP address of the telephone 213-5 in telephone communication using the IP telephone network 203. Uses the expression "EA01".

Next, the user service server 313-6 sets at least the user's telephone number " Tel-No-1 ", the external IP address " EA01 ", and the internal IP address " IA01 &quot; Notify 5 (step P10 3).

The telephone management server 313-5 stores three pieces of information corresponding to each of these three pieces of information: the user telephone number "Tel-No-1", the external IP address "EA01", and the internal IP address "IA01". The server 313-2 is notified (step P105). The telephone domain name server 313-2 is a resource record which is an operation rule of a domain name server in which user telephone numbers " Tel-No-1 ", " external IP address ", " internal IP address " record) or the like (step P106).

The telephone management server 313-5 also informs the table management server 313-3 of the four addresses " EA01, EA81, IA01, IA81 " (step P107). In addition, the telephone management server 313-5 always holds the external IP address "EA81" and the internal IP address "IA81" of the alternative telephone management server 313-1.

When the table management server 313-3 informs the network node device 208-1 of the four addresses " EA01, EA81, IA01, and IA81 " (step P108), the network node device 208-1 reads FIG. As shown in the figure, four addresses " EA01, EA81, IA01, and IA81 " shown in the first record of the address management table 360-1 in the network node device 208-1 are retained (step P109). Here, the address " IA01 " is an IP address assigned to the connection point (logical terminal) of the communication line 210-1 and the network node device 208-1, and subsequently assigned to the logical terminal of the communication line 210-1. This is called the internal IP address. At this point, the second row of the address management table 360-1 is blank.

The first row of the address management table 360-1 is referred to as an IP communication record of the address management table of the network node apparatus, and the source external IP address "EA01", the destination external IP address "EA81", and the source internal IP address "IA01". Is defined by the destination internal IP address " IA81 ". This IP communication record is specifically referred to as an IP communication record of the address management table of the network node device which sets the IP communication path between the proxy telephone management server 313-1 and the media router 212-1.

Similarly, the user 227-2 wishing to use the IP telephone requests the use of the IP telephone service to the IP telephone receiver 228-2 belonging to the telecommunication company 2 (step P110 in Fig. 75). The acceptor 228-2 obtains the user name or address, which is the application information of the IP phone, the payment method of the communication fee, the user telephone number "Tel-No-2" from the user 227-2, and the media router 212. -2) external IP address " EA02 ", identification symbol " L210-5 " of communication line 210-5 that the user uses to connect to media router 212-2, and this communication line 210-. 5) The network node device identification symbol " NN-209-2 " of the network node device 209-2 to which it is connected is input to the user service server 314-6 (step P111). Here, the IP address "EA02" acquired by the user 227-2 is presented to the IP telephone receiver 228-2.

The user sets the IP address "EA02" corresponding to the user telephone number "TeI-No-2" in the media router 212-2. Next, the user service server 314-6 gives the user 227-2 the user identification symbol " UID-2 " for identifying the received telephone user, and the user (e.g., to correspond to the external IP address " EA02 " 227-2) internal IP address " IA02 " At the same time, it is held in the database of the user service server (step P112). Since the telephone 214-4 uses the external IP address "EA02" corresponding to the telephone number "Tel-No-2", in telephone communication using the IP telephone network 203, the external IP address of the telephone 214-4. Uses the expression "EA02".

Next, the user service server 314-6 uses the IP management means for at least the user's telephone number " Tel-No-2 ", the external IP address " EA02 ", and the internal IP address " IA02 " (314-5) is notified (step P113). The telephone management server 314-5 sends these three pieces of information to the telephone domain name server 314-2, that is, the user telephone number "TeI-No-2", the external IP address "EA02", and the internal IP address "IA02". Notify it (step P115). The telephone domain name server 314-2 holds a set of information corresponding to each other of the user telephone number "Tel-No-2", the external IP address "EA02", and the internal IP address "IA02" in the form of a resource record or the like. (Step P116). The telephone management server 314-5 also informs the table management server 314-3 of the four addresses " EA02, EA82, IA02, and IA82 &quot; (step P117).

The telephone management server 314-5 always holds the external IP address " EA82 " and the internal IP address " IA82 " of the alternative telephone management server 314-1. In addition, the telephone domain name servers 313-2 and 314-2 have the same redialing function as the domain name servers used on the Internet, so that the telephone domain name servers can exchange information with each other when necessary. (Step P120).

The table management server 314-3 informs the network node device 209-2 of the four addresses " EA02, EA82, IA02, and IA82 " (step P118), and the network node device 209-2 shows FIG. As shown in the figure, four addresses " EA02, EA82, IA02, and IA82 " are held in the first record of the address management table 360-2 in the network node device 209-2 (step P119). Here, the address "IA02" is an internal IP address assigned to the connection point (logical terminal) of the communication line 210-5 and the network node device 209-2. At this point in time, the second row of records in the address management table 360-2 is blank. This IP communication record is, in particular, an IP communication record of an address management table of a network node device which sets an IP communication path between the proxy telephone management server 314-1 and the media router 212-2.

<< communication path establishment phase >>

74, 76 to 78, a description will be given of a terminal-to-terminal communication connection control method for making a telephone call from telephone 213-5 to telephone 214-4.

Media router 212-1 has telephone number "Tel-No-1" and external IP address "EA01", and media router 212-2 has telephone number "Tel-No-2" and external IP address " EA02 ". When the telephone 213-5 is talking to another telephone, the telephone number "Tel-No-1" assigned to the media router 212-1 is used. When the telephone 214-4 is talking to another telephone, The telephone number " Tel-No-2 " assigned to the media router 212-2 is used.

<< connection phase >>

When the user picks up the handset of the telephone 213-5 (off-hook), dials and enters the telephone number "Tel-No-2" of the communication counterpart telephone 214-4, and transmits it to the media router 212-1. (Step P200), the media router 212-1 responds (step P201).

Next, the media router 212-1 receives an IP packet containing at least the source telephone number " Tel-No-1 ", the destination telephone number " Tel-No-2 ", and user-Info. 379 of 79 is formed, and the call setup process of the telephone is started by transmitting to the network node device 208-1 (step P204). The user-information information (User-Info) can be sent to the media router 212-2 in step P219 in the following procedure, for example, a telephone call identifier ("C-" for managing the telephone call on the user side). id "), the identification symbol of the voice compression system of an IP telephone, the identification symbol of a voice code conversion code, and the like. The payload portion of the IP packet 379 in FIG. 79 is a UDP segment, and for example, the source port number and the destination port number are "5060", and the telephone communication in the media routers 212-1 and 212-2 is performed. A program for access control can be used to distinguish it from others.

Upon receiving the IP packet, the network node device 208-1 searches the address management table 360-1 shown in FIG. 76, and as the external IP address, transmit source IP address is " EA01 " The record containing "EA81" as a destination IP address is searched. In this example, when the first row of records from the top of the address management table 360-1, that is, the record "EA01, EA81, IA01, IA81" is found, the third and fourth IP addresses described in the record are found. An IP packet encapsulation technique is applied using " IA01 " and " IA81 " to form an IP packet 380 which is an internal IP packet shown in Fig. 80, and an alternative telephone management server 313- having an IP address of " IA81 ". To 1) (step P205). Here, the payload portion of the IP packet 380 is the IP packet 379.

Upon receiving the IP packet 380, the surrogate telephone management server 313-1 generates an IP packet 381 whose payload portion is an IP packet 379, and the telephone management server 313 having an IP address of "IA91". -5) (step P206). The telephone management server 313-5 uses the communication line identifier (CIC-1-2) as a combination of the source telephone number "Tel-No-1" and the destination telephone number "Tel-No-2", for example. It sets CIC-1-2 = "Tel-No-1" + "Tel-No-2", and holds the communication line identifier (CIC-1-2) inside the telephone management server 313-5. Here, "+" means linking telephone numbers (connection of data).

The telephone management server 313-5 notifies the telephone domain name server 313-2 of the source telephone number "Tel-No-1" and the destination telephone number "Tel-No-2" received in step P206 above. (Step P207), the external IP address "EA01" and the internal IP address "IA01" corresponding to the telephone number "Tel-No-1" 1: 1 in the telephone domain name server 313-2, and the telephone number "Tel". IP address "EA02" and internal IP address "IA02" corresponding to -1 to -No-2 "are received (step P208). Here, the telephone domain name server 313-2 inquires and acquires the IP address information of the telephone number "Tel-No-2" to the telephone domain name server 314-2 using the recursive calling function. The telephone management server 313-5 has the IP address "TA01" received from the telephone domain name server 313-2 and the source IP address ("EA01") acquired from the inside of the IP packet 381 in step P206. If there is a mismatch, the telephone connection process is stopped if there is a mismatch, and if it is matched, the IP address "EA01" of the source telephone and the internal IP are determined based on the information of the communication line identifier (CIC-1-2) held above. The address "IA01", the IP address "EA02" of the destination telephone, and the internal IP address "IA02" are additionally retained. The IP packet for server-to-server communication in the integrated IP communication network transmits and receives an IP packet 382 in the format shown in FIG. 82 using an internal IP address. The network node device is not a server. The IP packet transmitted / received between the network node device and the surrogate telephone management server is an IP packet of the encapsulated form shown in FIGS. 80 and 84, and the IP packet transmitted / received between the network node device and the media router is shown in FIG. IP packet before encapsulation with external IP address.

Next, the telephone management server 313-5 transmits IP address "EA01" of the source telephone, "IA01" of the internal IP address, source telephone number "Tel-No-1", IP address "EA02" of the destination telephone, IP packet (IAM packet) including internal IP address "IA02", destination telephone number "Tel-No-2", user individual information (User Info), and communication line identifier (CIC-1-2) Via representative server 313-7 of company 1 (step P214), via representative server 314-7 of communication company 2 (step P215), and to telephone management server 314-5 of communication company 2 Transmit (step P216). The telephone management server 314-5 includes four IP addresses "EA01, IA01, EA02, IA02", two telephone numbers "Tel-No-1" and "Tel-No-2", a communication line identifier (CIC- 1-2) and user-information information (User-Info) are received and retained internally except for user-information information (User-Info).

The telephone management server 314-5 having the internal address "IA92" also notifies the alternate telephone management server 314-1 having the internal IP address "IA82" of the IP packet 383 in FIG. 83 (step P217). ). Here, the IP packet 383 includes IP address "EA01" of the source telephone, IP address "EA02" of the destination telephone, source telephone number "Tel-No-1", destination telephone number "Tel-No-2", User additional information (User-Info) is included. The alternative telephone management server 314-1 forms the IP packet 384 in FIG. 84 and transmits it to the network node device 209-2 (step P218). The network node device 209-2 sends an IP packet. The IP packet excluding the header 384 is decapsulated to form an IP packet 385 shown in FIG. 85, and transmitted to the media router 212-2 (step P219). The media router 212-2 includes the IP address "EA01" of the source telephone, the IP address "EA02" of the destination telephone, the source telephone number "Tel-No-1", the destination telephone number "Tel-No-2", Acquire user additional information (User-Info).

Next, the media router 212-2 attaches the two telephone numbers " Tel-No-1 " and " Tel-No-2 " to receive the information informing the incoming call of the telephone management server 314-5. (Steps P221, P222, and P223), the telephone management server 314-5 receives the communication line identifier (CIC-1) from the received two telephone numbers " Tel-No-1 " and " Tel-No-2 ". -2), and next, the reception confirmation IP packet (ACM packet) of the information including the communication line identifier (CIC-1-2) is passed through the telephone management server 313-5 to the media router 212-1. (Steps P224 to P229).

Next, the media router 212-2 informs the telephone 214-4 of the telephone call (incoming) (step P230), and the telephone 214-4 sounds a telephone ring tone when it knows the telephone call. The media router 212-2 indicates that the telephone 214-4 of the called telephone number " Tel-No-2 " is being called by the source telephone number " Tel-No-1 " and the destination telephone number " Tel- ". A set of No-2 "is attached to the telephone management server 314-5 via the network node device 209-2 (step P231), and via the alternate telephone management server (step P232) ( Step P233). The telephone management server 314-5 of the telecommunication company 2 uses the set of the source telephone number "Tel-No-1" and the destination telephone number "Tel-No-2" sent from the media router 212-2. The communication line identifier (CIC-1-2) is restored, and next, an acknowledgment IP packet (CPG packet) of the information including the communication line identifier (CIC-1-2) is formed to establish a telephone management server (313-5). (Steps P234, P235, P236). The telephone management server 313-5 receives the CPG packet and reads out the communication line identifier CIC-1-2 from the CPG packet.

Next, the telephone management server 313-5 reads out the address and telephone number recorded and held in step P214 using the communication line identifier CIC-1-2, and at least the media router 212 to which the source telephone is connected. -1), IP address "EA02" of the media router 212-2 to which the destination telephone is connected, source telephone number "Tel-No-1", destination telephone number "Tel-No-" When 2 "is transmitted to the alternative telephone management server 313-1 (step P237), it is notified to the media router 212-1 through the network node device 208-1 (step P238) (step P239). The media router 212-1 informs the source telephone 213-5 that the destination telephone 214-4 is being called (step P240), and the source telephone 213-5 sounds a ring tone.

On the other hand, when the user of the telephone 214-4 hears a telephone ring tone and picks up the telephone's handset (off-hook), the IP telephone 214-4 notifies the media router 212-2 of the off-hook (step P241). The media router 212-2 receives the off-hook notification via the network node device 209-2 (step P242), and via the alternative telephone management server (step P243), and the telephone management server 314-5. (Step P244). The telephone management server 314-5 of the telecommunication company 2 restores the communication line identifier (CIC-1-2) from the set of the source telephone number "Tel-No-1" and the destination telephone number "Tel-No-2". Then, an acknowledgment IP packet (ANM packet) of the information including the communication line identifier (CIC-1-2) is formed and transmitted to the telephone management server 313-5 (steps P245, P246, and P247). The telephone management server 313-5 receives the ANM packet and reads out the communication line identifier (CIC-1-2) from the ANM packet.

The telephone management server 314-5 reads out the IP address and telephone number stored and stored at the time of step P217, using the communication line identifier (CIC-1-2) held at the time of step P245. Next, the telephone management server 314-5 is configured with IP address "EA01" of the source telephone and "IA01" of the internal IP address, IP address "EA02" of the media router 212-2 to which the destination telephone is connected, and internal. The table management server 314-3 notifies "IA02" of the IP address (step P250), the table management server 314-3 communicates with the communication line identifier (CIC-1-2), and the IP address "EA01" of the source telephone. &Quot; and IA01 of internal IP address ", IP address " EA02 " of destination telephone and " IA02 &quot; of internal IP address, while retaining therein an address management table 360- in the network node device 209-2. 2) (Step P251) This state is shown as the 2nd row record of the address management table 360-2 of FIG.

The telephone management server 313-5 reads out the IP address and telephone number held and stored at the time of step P214, using the communication line identifier CIC-1-2 read out. Next, the telephone management server 313-5 transmits the communication line identifier CIC-1-2, the IP address " EA01 " and the internal IP address " IA01 " of the transmitting media router 212-1, and the destination media router. The IP address " EA02 " and the internal IP address " IA02 " of the 212-2 are notified to the table management server 313-3 (step P252), and the table management server 313-3 sends a communication line identifier (CIC- 1-2), the IP address " EA01 " of the source telephone and " IA01 " of the internal IP address, the IP address " EA02 " of the destination telephone, and " IA02 " (208-1) is retained in the internal address management table 360-1 (step P253). This state is shown as the second row record of the address management table 360-1 in FIG.

The second row record of the address management table 360-1 in Fig. 76 is the "IP communication record of the address management table" set in the network node apparatus, and the contents of this IP communication record are the sender external IP address "EA01" and the destination external. It defines that it is defined by IP address "EA02", a sender internal IP address "IA01", and a destination internal IP address "IA02".

The second IP communication record of the address management table 360-1 includes the external IP address " EA01 " and the external IP address " EA02 ", and the media router 212-1 to which the external IP address " EA01 " The IP communication path between the media routers 212-2 to which the external IP address "EA02" has been assigned is determined. Similarly, the IP communication record of the second row of the address management table 360-2 also defines an IP communication path between the media router 212-1 and the media router 212-2.

In addition, the source external IP address "EA01" is set to correspond to the telephone number "Tel-No-1" and 1: 1, and the destination external IP address "EA02" is set to the telephone numbers "Tel-No-2" and 1: 1. If the correspondence is set to 1 and the source and destination are not distinguished, the IP communication record of the address management table of the network node device is simply an IP between the telephone number "Tel-No-1" and the telephone number "Tel-No-2". Record of the address management table for determining the communication path.

The step P245 is a process of notifying response information for confirming call setting, that is, possible to start telephony communication between the telephone 213-5 and the telephone 214-4, and the telephone management server 314-5, for example. Communication line identifier (CIC-1-2), IP address "EA01" of source media router 212-1, IP address "EA02" of destination media router 212-2, source telephone number "Tel-No- 1 ", the destination telephone number" Tel-No-2 "is notified to the charging management server 314-4 based on the telephone communication start possible time (step P254), and the charging management server 314-4 Communication line identifier (CIC-1-2), source telephone number "Tel-No-1", destination telephone number "Tel-No-2", IP address "EA01" of source media router 212-1, number The IP address " EA02 " or the like of the Shinji media router 212-2 can be recorded and stored (step P254).

Similarly, the billing management server 313-4 includes the source telephone number "Tel-No-1", the destination telephone number "Tel-No-2", the IP address of the source telephone "EA01", the IP of the destination telephone. The address " EA02 " or the like can be recorded and stored (step P255). The telephone management server 313-5 also responds to the telephone call by the user of the destination telephone 214-4 by picking up the handset, that is, the response to the telephone call via the proxy telephone management server 313-1. (Step P256), via the network node device 208-1 (step P257), and via the media router 212-1 (step P258), and notify the telephone 213-5 (step P259). .

The series of steps (step P259) until the IP telephone 213-5 described above informs the telephone 213-5 of the completion of call setup from step P200 with the handset is referred to as a connection phase of telephony communication. do. In the above-described terminal-to-terminal connection control, the router 219-1, the representative servers 313-7, 314-7, and the router 219 from the network node device 208-1 to the communication line 370-1. -2) The communication line connected to the network node device 209-2 via the communication line 370-5 is called a "connection control line" inside the IP telephone network 203. In addition, the access control line is used to transmit and receive IP packets for communication connection control between terminals.

<< communication phase >>

It demonstrates with reference to FIG. 86-89. The voice inputted to the telephone set 213-5 is transmitted to the media router (step P300), and the media router digitizes the voice to form an IP packet 387 and transmits it to the network node device 208-1 (step P301). ). IP packet 387 is encapsulated and converted into internal IP packet 388, communication line 370-3, routers 219-5, 219-7, 221-1, 219-10, 219-9, communication The network node device 209-2 is reached through the line 370-6 (step P302), and is converted into an IP packet 389 by decapsulation except the IP header, and then passes through the media router 212-2. (Step P303), it is sent to the telephone set 214-4 (step P304). The voice of the user of the telephone 214-4 is reversed, that is, the media router 212-2 (step P305), the network node device 209-2 (step P306), the routers 219-9, 219-10, 221-1, 219-7, 219-5, reach network node device 208-1 (step P307), pass through media router 212-1 (step P308), and telephone 213-5. (Step P309).

In the communication phase, payload portions of IP packets 387 and 389 are UDP segments, and source and destination UDP port numbers are, for example, "5004", "5006", "5010", By changing to "5012", "5016", and the like, telephone communication that transmits other voices is possible. IP packet 388 containing digitized voice passes from network node device 208-1 through communication line 370-3 to routers 219-5, 219-7, 221-1, 219-10, 219-. 9) Since it is transmitted through the communication line connected to the network node device 209-2 through the communication line 370-6, this IP communication line is called a "voice communication line" inside the IP telephone network 203. Can be distinguished from the "connection control line" of the IP telephone network 203 in the connection phase.

In the communication phase, the second row of the record of the address management table 360-1 in FIG. 76, that is, the source external IP address "EA01", the destination external IP address "EA02", the source internal IP address "IA01", and the destination internal IP IP communication records with the address " IA02 ", i.e., records in the address management table which define the IP communication path between the telephone number " Tel-No-1 " and the telephone number " Tel-No-2 ".

<< liberation phase >>

Referring to Fig. 90, when the user of the telephone 213-5 puts the handset to end telephony, if the media router 212-1 is notified of the end of telephony (step P400), the media router 212 -1) generates an IP packet including at least an indication of a telephony release request, a source telephone number " Tel-No-1 ", and a destination telephone number " Tel-No-2 " (Step P401), the network node device 208-1 generates an IP packet encapsulating the received IP packet using the first row record of the address management table 360-1 in FIG. The data is sent to the server 313-1 (step P402). Subsequently, the alternative telephone management server 313-1 displays the indication of the telephone release request originally generated by the media router, the source telephone number "Tel-No-1", and the destination telephone number "Tel-No-2". An IP packet to be included is formed and transmitted to the telephone management server (step P403). The format of the IP packet and the method of setting the IP address used in steps P401, P402, and P403 described above are the same as those of steps P204, P205, and P206 in the telephony connection phase.

The telephone management server 313-5 restores the communication line identifier (CIC-1-2) from the two telephone numbers " Tel-No-1 " and " Tel-No-2, " An IP packet (REL packet) containing the communication line identifier (CIC-1-2) is formed and transmitted to the representative server 313-7 of the telecommunication company 1 (step P404). The IP packet reaches the telephone management server 314-5 under management of the communication company 2 via the representative server 314-7 of the communication company 2 (step P405) (step P406).

Next, the telephone management server 313-5 sends the proxy telephone management server 313-1 and the network node device 208-1 with the release completed IP packet, which reports that the release request is performed in steps P400 to P403. It returns to the media router 212-1 via (steps P407, P408, and P409). In addition, the telephone management server 313-5 transmits an IP packet including a communication line identifier (CIC-1-2) to the table management server 313-3 (step P433). Since the table management server 313-3 holds the address corresponding to the communication line identifier CIC-1-2 after the step P252, the four IP addresses " EA01, EA02, IA01, IA02 " (deletion), the second row of the address management table 360-1 in the network node apparatus 208-1 shown in Fig. 76, that is, the source external IP address " EA01 ", the destination external IP. The address "EA02", the sender internal IP address "IA01", the destination internal IP address "IA02", and the IP communication record are erased (step P434). That is, the record of the address management table which defines the IP communication path between telephone number "Tel-No-1" and telephone number "Tel-No-2" is erased.

When the telephone management server 314-5 receives the IP packet including the indication of the telephone communication release request and the communication line identifier (CIC-1-2) by step P406, the telephone management server 314-5 forms a release request IP packet to substitute the telephone management server. The IP packet transmitted to 314-1 and indicating the release request instruction reaches the media router 212-2 via the network node device 209-2 (steps P411, P412, and P413). In addition, the telephone management server 314-5 forms an IP packet (RLC packet) including a communication line identifier (CIC-1-2) to report that the step P411 has been performed, and transmits the RLC packet to the communication company. It transmits to the representative server 314-7 of 2 (step P414). The RLC packet reaches the telephone management server 313-5 under the management of the telecommunication company 1 via the representative server 313-7 of the telecommunication company 1 (step P415). When the telephone management server 313-5 which has received the release completion IP packet notifies the charging management server 313-4 of the end of the telephony communication (step P442), the charging management server 313-4 transmits the communication line. The end of the telephone communication identified by the number (CIC-1-2) is found, and the result is recorded internally.

Next, the telephone management server 314-5 transmits the IP packet including the communication line identifier (CIC-1-2) to the table management server 314-3 (step P431), and the table management server 314-. 3) shows four addresses of "EA02", "EA01", "IA02", and "IA01" which are the contents of the second row record of the address management table 360-2 in the network node device 209-2 shown in FIG. Erase the set (step P432). When the media router 212-2 learns the telephony release request by step P413, it sends a call disconnection instruction to the telephone 214-5 (step P420), and then releases the report of performing the release request by step P413. The completed IP packet is returned to the network node device 209-2, the alternative telephone management server 314-1, and the telephone management server 314-5 (steps P421, P423, P424). The telephone management server 314-5 notifies the charging administration server 314-4 of the termination of the telephony of the call number (step P441), and the charging management server 314-4. ) Knows the end of the telephone communication identified by the communication line number (CIC-1-2), and records the result therein.

<< matters attached to telecommunication connection control >>

Consider a case where the telephone user does not leave the telephone communication for a long time and does not terminate the telephone communication, that is, the case where the telephone termination step P400 shown in FIG. 90 is not performed. In this case, it is anticipated that the telecommunication fee will be increased indefinitely. To avoid this situation, for example, when the telephone management server 313-5 inquires and detects the charging management server 313-4 every long time, for example, every 24 hours, and detects long-term telephone communication, Except for steps P400 to P403 in FIG. 90, steps P404, P407, P433, and P442 may be independently performed.

<< other communication charge collection method >>

As for the communication fee, for example, a billing information collection server for telecommunication company 1 is installed in the integrated IP communication network 201, and the billing information collected by the billing management server 313-4 is collected to provide user service. The server 313-6 can be notified and the telephone user can be charged from the billing server. Telecommunications company 2 can also set up a billing information collection server. The charged information collected as described above may be exchanged between the telecommunication company 1 and the telecommunication company 2 using the IP communication means via the telecommunication company representative servers 313-7 and 314-7.

<< case where telecommunication company is one company >>

Even when the operation management range 206-2 of the communication company 2 in FIG. 74 does not exist and the IP telephone network 203 becomes the operation management range of the communication company 1, the above-described operation of the dial-up phase is possible. For this reason, as shown in FIG. 91, the operation management range 206-2 of the communication company 2 is changed to the operation management range of the communication company 1, and the representative server 314-7 of the communication company 2 is omitted, and the router ( 219-1) and the router 219-2 are connected by an IP communication line. In this way, in the connection phase of the telephony communication, steps P214 to P216 shown in FIG. 78 become P214X shown in FIG. 92, and steps P224 to P226 shown in FIG. 78 become P224X shown in FIG. 92, and FIG. 78. Steps P234 to P236 shown become P234X shown in FIG. 92, steps P245 to P247 shown in FIG. 78 become P245X shown in FIG. 92, and the other steps are the same.

The telephony preparations of telecom company 2 are all changed to the telephony preparations of telecom company 1. During the series of steps in the telephony connection phase and the telephony release phase, the communication between the phone management server 313-5 and the phone management server 314-5 is left, and the representative server 313-7 of the communication company 1 is left. ) And a series of steps handled by the representative server 314-7 of the telecommunication company 2 are omitted. Further, the telephone management server 313-5 and the telephone management server 314-5 may be integrated into the telephone management server. In this way, in the telephone communication connection phase, steps P214X, P224X, P234X, P245X, and P254X shown in FIG. 92 are omitted, and steps P217, P223, P233, P244, P250, and P251 are P217x and P223x shown in FIG. 93, respectively. , P233x, P244x, P250x, and P251x, and the other steps are the same.

<< Description of connection control of telephone management server 1 >>

In step P214, which performs communication from the telephone management server 313-5 to the server 313-7 representing the telecommunication company, the IP telephone network in which the destination telephone number "TeI-No-2" is managed by the telecommunication company. Before querying the telephone domain name server 313-2 whether it belongs to (subscribed to) or is subscribed to an IP telephone network managed by another telecommunications company, it is possible to perform the following procedure.

The telephone management server 313-5 solves this problem by using the "telephony company identification table of telephone numbers". When explaining according to the example of the telephone company division table of the telephone number shown in FIG. 94, it is a record of the sequence number 1 of a telephone company division table, and "81-3-5414-xxxx" and "Are you own?" "No" and "Communication company identification information" are shown as "Com-130". "xxxx" means "0000" to "9999" in decimal, and in this example, 81-3-5414-0000 to 81-3-5414-9999 of the telephone number are the communication identified by Com-130. It indicates that the company belongs to an IP telephone network managed by the company. In addition, "1-2245-5678" of the telephone number on the record of the sequence number 2 of the communication company division table shows that the communication company identified by Com-025 belongs to the IP telephone network managed and operated. &Quot; 81-47-325-3887 " of the telephone number on the record denotes that it belongs to an IP telephone network managed and operated by the telecommunication company to which the telephone management server 313-5 belongs.

<< Description of connection control of telephone management server 2 >>

In step P214, when the telephone management server 313-5 communicates with the server 313-7 representing the telecommunication company, the IP telephone of the destination telephone number " Tel-No-2 " It is also possible to know which network node apparatus the telephone whose telephone number is " Tel-No-2 " to which the other telephone management server is connected is subscribed, even if it is found to be under the following, which will be described below. The telephone management server 313-5 solves this problem by "phone management server classification table of telephone numbers." It demonstrates according to the example of the telephone management server division table of the telephone number shown in FIG.

The telephone number " 81-47-325-3887 " on the record of the sequence number 1 of the telecommunication company division table indicates that the telephone management server 313-5 is subscribed to the network node device (that is, the communication line is connected). . The telephone number " 81-2245-56 xx " on the record of sequence number 2 of the telecommunication company identification table is the telephone company 81-2245-5600 to 81-2245-5699, wherein the telephone management server has an IP address of " 100.10.11.40 " Indicates that a network node device that manages and manages a network node (that is, a communication line is connected). Next, the telephone number " 81-6-1234-xxxx " on the record of sequence number 3 of the telecommunication company identification table is a network in which telephone numbers 81-6-I234-0000 to 81-6-1234-9999 are managed by the telecommunication company. Indicates that the node device is subscribed (that is, a communication line is connected).

<< Management management of network by operation management server >>

The operation management server 313-9 of the telecommunication company 1 may periodically or from time to time operate network node devices 208-1 and 208-2 and routers 219- that are resources within the operation management range 206-1 of the telecommunication company 1. 1, 219-3, 219-5, 219-6, 219-7), telephone domain name server 313-2, telephone management server 313-5, alternative telephone management server 313-1, table management ICMP or by using IP communication means such as server 313-3, billing management server 313-4, representative server 313-7, user service server 313-6, telephone gateway 209-1, or the like. By means of sending and receiving packets, it is checked whether these resources are normal or whether communication lines between resources are normal (fault management), and whether or not the congestion of IP packets in the network is excessive. By (communication quality management), the inside of the operation management range 206-1 of the communication company 1 is collectively managed. The failure status or communication quality status of the network resource including the communication line obtained as a result of the operation management may be reported to the telephone user 227-1 through the user service server 313-6.

Similarly, operation management server 314-9 of communication company 2 periodically or occasionally communicates with various resources within operation management scope 206-2 of communication company 2 to check whether these resources are normal or between resources. Examines whether the communication line is normal (fault management) and monitors whether or not the congestion of IP packets in the network is excessive (communication quality management), thereby operating within the operation management range 206-2 of the telecommunication company 2 Manage and manage all of them. The operation management result may be reported to the telephone user 227-2 past the user service server 314-6.

Of the telephone network 203 inside the IP transmission network 201 between the IP telephone 213-5 and the IP telephone 214-4 by the network management management by the operation management servers 313-9 and 314-9. The reliability of the communication connection control between terminals can be improved. Similarly, the economic base of the network operation of the telecommunication company is maintained by the communication charge collection means by the charge management servers 313-4 and 314-4, so that the communication between the terminals of the telephone network 203 inside the IP transmission network 201 is carried out. The reliability of connection control can be improved.

Example 6 is summarized and supplemented as follows. That is, the IP transport network includes at least a network node device, a telephone management server, a media router, a telephone domain name server, a table management server, and user i (i = 1, 2, ...) is a user media router outside of the IP transport network. Connects one or more telephones to the media router of user i by setting a separate external IP address " EA-i " to the one or more of the network node devices through the communication line, and the network of the communication line The node apparatus side end portion (logical terminal) is given an internal IP address " IA-i " used for communication of user i, and the user's individual telephone number is assigned to the media router. Further, the telephone domain name server has a set of a user's individual telephone number, the external IP address "EA-i" and the internal IP address "IA-i" of the media router, so that the telephone domain name server is a user. In response to an individual telephone number, an external IP address and an internal IP address are returned, and an IP communication record for setting an IP communication path between a media router and an alternative telephone management server is set in the network node device.

The IP communication record is used for the request of the calling telephone, which is transmitted to the telephone management server via an alternative telephone server, and the telephone management server requests the telephone domain name server, and the external IP address and internal IP address of the calling media router are transmitted from the calling telephone number. From the IP address ("EA-i, IA-i") and the destination telephone number, the external IP address and internal IP address ("EA-j, IA-j") of the destination media router are obtained, and the table management server Sets these IP addresses as IP communication records used for telephony communication between the source telephone and the destination telephone, respectively, at the sending network node device and the destination network node device. Upon requesting a call setup from the source telephone, the source media router sends an IP packet containing the destination telephone number and the source telephone number to the source telephone management server, and the source telephone management server identifies the communication line for telephone voice. Line number (CIC) to say is decided collectively from set of destination telephone number and source telephone number.

The source telephone management server then sends an " IAM packet requesting telephone call setup " including the source telephone number, the destination telephone number, and the line number to the destination telephone management server, and the destination telephone management server. When the server notifies the destination media router of an incoming call and the phone is allowed to receive the call, the destination phone management server sends the "ACM packet reporting the IAM packet reception" to the source media router via the source phone management server. Send to In addition, the destination media router requests a telephone call setup from the destination telephone. When the phone rings, the media router notifies the destination telephone management server that it is busy and the destination telephone management server sends a "CPG packet for notifying call reception" to indicate that it is busy. Send to the server, and the source-side telephone management server informs the source-side telephone that it is in a call reception via the media router.

If the destination telephone responds to the call setup request, the response is passed through the destination media router to the destination telephone management server, and the destination telephone management server is " ANM packet indicating the response to the call setup request. &Quot; Is sent to the source telephone management server, and the source telephone management server informs the source media router of the response to the call setup request, and the source telephone stops the ring tone and moves to the call phase. When the call of the source or destination telephone is terminated and the telephone call disconnection request is notified, the disconnection request is notified to the telephone management server via the media router.

The telephone call disconnect requesting telephone management server forms a " REL packet requesting termination of telephony " using a line number (CIC) and transmits it to the other to-be-digested telephone management server. RLC packet reporting the REL packet reception. The cut telephone management server informs the disconnect requesting media router of the telephony termination report.

The telephone management server may collect a telephone communication record including a line number, a communication time and a telephone number after the completion of the telephone communication, and notify the operation management server and the billing server. The IAM, ACM, CPG, ANM, REL, and RLC are transmitted and received in the terminal-to-terminal communication connection control between the telephone management server and the relay telephone management server or the terminal-to-terminal communication connection control between two telephone management servers. IP packets are transmitted and received between the telephone management server and the media router to control access between terminals.

The payload portion of the IP packet is a UDP segment, and the dial-up connection phase and the telephone release phase are one port number, enabling the use of a single call control program that manages the connection phase and the telephone release phase in different telephony. Doing. Also, in the telephone call phase, by assigning different UDP port numbers to different telephones, different voices can be transmitted from telephone to telephone even when the media router is the only IP address. The telephone management server performs a telephony connection phase with a source media router and a destination media router via a surrogate telephone management server so that one telephone management server functions solely as a calling telephone management server and a receiving telephone management server. And telephone release phase procedure can also be performed.

The telephone management server may use a telephone company identification table of the telephone number to know whether the destination telephone number belongs to an IP telephone network managed by its telecommunication company or subscribed to an IP telephone network managed by another telecommunication company. It may be. In order to know which network node apparatus the telephone having the destination telephone number is subscribed to, the telephone management server identification table of the telephone number may be used. The operation management server of the telecommunication company exchanges information with network node devices, various servers, and telephone gateways within the operation management range of the telecommunication company to unilaterally manage and operate the network, thereby improving the reliability of communication connection control between terminals in the network. Or in connection with a billing management server to improve the reliability of the terminal-to-terminal communication connection control of the IP transport network.

7. Seventh Embodiment of Different Media Router Structures:

FIG. 96 is a diagram for explaining a method for assigning an IP address and a phone number to a media router, and FIG. 97 is a diagram for explaining the encapsulation of IP packets of a network node device, which will be described with reference to these drawings. do.

The media router 530 accommodates the IP phones 515-1 to 515-4 and the analog phones 516-1 to 516-3, and the logic for transmitting and receiving IP packets from the line interface unit 533. It is connected to the network node device 540 via communication lines 539-1 to 539-3. Here, the physical communication line 538 includes all of the logical communication lines 539-1 to 539-3.

The media router 530 performs main processing of the media router 530 other than the telephone call control, and includes an analog interface unit 532 and a line interface unit 533 having a media router main unit 531 and a connection interface with an analog telephone. And an address telephone number correspondence table 534 and a telephone management table 535, and the media router main part 531 has IP addresses "EA01", "EAI2", "EA13" and "ADR" therein. IP address "EA01" with telephone number "Tel-No-1", IP address "EA12" with telephone number "Tel-No-12", IP address "EA13" with telephone number "Tel-No-13" Each corresponds to 1: 1, and this state is shown in the address telephone number correspondence table 534. FIG. Telephone numbers assigned to IP telephones and analog telephones are managed using an address management table. Therefore, when changing the telephone number, the address management table is rewritten.

There are ports 538-1 to 538-7 in the main part of the media router 531, and these ports are assigned port numbers of "1" to "7", respectively, and these ports are passed through the communication line to the IP telephone. Are connected directly or indirectly to the analog telephones 516-1 to 516-3 via the analog interface unit 532. IP telephones 515-1 to 515-4 are assigned identification names of " Id-5 " to " Id-8 " and IP addresses " AD01 " to " AD04 ", respectively. It is shown in the record whose port number is 1-4. "D" in the telephone management table represents an IP telephone, and "A" represents an analog telephone. IP address "EA01" is assigned to the port 532-1, IP address "EA12" is assigned to the port 532-2, and IP address "EA13" is assigned to the port 532-3. Ports 538-1 and 532-1 are connected by a communication line, and ports 538-7 and 532-3 are connected by a communication line. The IP telephone 515-1 is connected to the port 538-1 through the communication line 517-1, so that the IP telephone 515-1 is connected to the network node device via the media router 530. IP address "EA01" can be used. Similarly, IP address "EA13" is fixedly assigned to analog telephone 516-3. The analog telephone 516-3 shows that when connected to the network node device via the media router 530, the IP address " EA13 " is always used. This state is shown in the record of port 1 and the record of port 7 of the address management table 535, respectively.

Ports 538-4 and 538-5 are connected via a communication line, and IP telephone 515-4 is a communication line 517-4, ports 538-4 and 538-5, and an analog interface 532. And an analog telephone 516-1 via a communication line 518-1, and telephone communication is possible between the IP telephone 515-4 and the analog telephone 516-1. Similarly, IP telephone 515-2 is connected to IP telephone 515-3 via communication line 517-2, ports 538-2 and 538-3, and communication line 517-3. Telephone communication is possible between IP telephones.

Telephone communication between two analog telephones is also possible by the function of the analog interface unit. IP telephones 515-1 to 515-4 digitize voice and transmit it in an IP packet, and restore the digitized voice to analog voice as an opposite function. The analog interface unit digitizes the voice received from the analog telephones 516-1 to 516-3 and sends it to the media router main unit 531, and restores the digitized voice received from the media router main unit 531 to analog voice as a reverse function. Send it to your analog phone.

<< serial order of media router and network node device for dialup >>

When the handset of the IP telephone 515-1 is lifted, the calling IP packet 520 is passed to the media router main portion 531 through the communication line 517-1. Here, the source IP address written in the header inside the IP packet 520 is "AD01", and the destination IP address is "ADR". The media router main section 531 returns an IP packet of " calling acceptance " to the IP telephone 515-1. Next, when the user of the IP telephone 515-1 dials and enters the telephone number " Tel-No-4 " of the communication counterpart, the source telephone number " A " calling setting " IP packet of a telephone including Tel-No-1 " and the telephone number " Tel-No-4 " of the communication counterpart is generated and transmitted to the media router 530.

The media router 530 receives the IP packet at the media router main unit 531 and forms an IP packet including at least the source telephone number "Tel-No-1" and the destination telephone number "Tel-No-4". And transmits to the network node device 540 to start the call setup process.

Upon receiving the IP packet 521, the network node device 540 searches the address management table 541 shown in FIG. 97, and the source IP address is "EA01" as the external IP address, and "EA81" as the destination IP address. The record to be included is searched. In this case, if the first row of records from the address management table 541 is found, that is, the record of "EA01, EA81, IA01, IA81", it is written in the third and fourth of this record. The IP addresses "IA01" and "IA81" are used to generate an internal IP packet 542 by applying an encapsulation technique of the IP packet, and transmit to the alternative telephone management server 545 having the IP address "IA81". Here, the payload portion of the IP packet 542 is the IP packet 521. Further, in the above description, since the physical communication lines 538 include all of the logical communication lines 539-1 to 539-3, the logical terminals 543-1 to 543-3 all have the same internal IP address value "IA01". This is an example.

8. Eighth Embodiment of Performing Closed-area Telephone Communication:

In FIG. 98, reference numeral 1001 denotes an integrated IP network, reference numeral 1002 denotes an IP data network, reference numeral 1003 denotes an IP telephone network, reference numeral 1004 denotes a voice video network, and reference numeral 1005 denotes an integrated IP communication network managed by a communication company 1. In the range, reference numeral 1006 is the range of the integrated IP network managed and operated by the telecommunication company 2. Reference numerals 1002 to 1004 are all IP transmission networks having IP packet transmission functions, and information can be exchanged by IP communication means for transmitting and receiving IP packets within the IP transmission network. The IP address used outside the integrated IP communication network 1001 is called an external IP address, and the IP address used internally is called an internal IP address. Reference numerals 1011 to 1017 are telephones, reference numerals 1021 to 1025 are media routers, reference numerals 1080 and 1081 are telephone gateways, reference numerals 1082 and 1083 are public switched telephone networks (PSTNs), and reference numerals 1084 and 1085 are telephones.

From the telephone 1011, the network node apparatus 1032, the communication line 1041, the media router 1022 via the media router 1021, the communication line 1040, the network node apparatus 1031, and the IP telephone network 1003 inside. ), A "terminal communication connection control method" for establishing a communication connection of the telephone to the telephone 1012.

The users of the telephones 1011 to 1013 determine in advance the respective telephone numbers and values of the external IP addresses given to the media router to which these telephones are connected. 100 and 101, the telephone 1011 gives an external IP address " EA1 " to the media router 1021 using the telephone number " Tel-No-1 ", and the telephone 1012 is a telephone. The media router 1022 is assigned an external IP address "EA2" using the number "Tel-No-2", and the telephone 1013 is assigned to the media router 1023 using the telephone number "Tel-No-3". Give the external IP address "EA3". The telephone number servers 1026 to 1028 all reply the external IP address "EA1" when the telephone number "Tel-No-1" is presented, and the external IP address "EA2" when the telephone number "Tel-No-2" is presented. If the telephone number "Tel-No-3" is presented, the external IP address "EA3" is set to reply. In this method, for example, a group of telephone numbers, such as extension telephone numbers "100" to "199", is mapped to a domain name "1" by a predetermined rule, for example, a rule in which 100 numbers are mapped to one. The known technique of name server (DNS) can be applied.

<< Ready for Telephony >>

Referring to Figs. 98 and 99, the user 1060 requests the telephone receiver 1061 to use the telephone (step A100 of Fig. 99), and the telephone receiver 1061 is the external IP address " EA1 " and " EA2 ", user name or charge method, identification symbol " L-1040 " of communication line 1040, identification symbol " NN-1031 " of network node device 1031, identification of communication line 1041 The symbol "L-1041" and the identification symbol "NN-1032" of the network node apparatus 1032 and the like are obtained from the user 1060 and notified to the user service server 1041 (step A101). The user service server 1041 determines the user identification symbol "UID-1" for identifying the user 1060, and user application information such as external IP addresses "EA1" and "EA2" obtained by the reception, user name, and the like. Is held in a database owned by the user service server 1041 (step A102).

Next, the user service server 1041 determines the external IP addresses " EA1 " and " EA2 " obtained by the above process, the identification symbols " L-1040 " and " L-1041 " When notifying the telephone management server 1042 of the symbols " NN-1031 " and " NN-1032 " (step A103), the telephone management server 1042 determines the internal IP addresses " IA1 " and " IA2 " "EA1, EA2, IA1, IA2" is notified to the table management server 1043 (step A107). Here, the internal IP address "IA1" is an internal IP address assigned to the connection point of the communication line 1040 and the network node device 1031, and "IA2" is assigned to the connection point of the communication line 1041 and the network node device 1032. It is an internal IP address and uses the identification symbols "NN-1031" and "NN-1032" of the network node device and the identification symbols "L-1040" and "L-1041" of the communication line to obtain the internal IP transmission network 1001. It is a value which is determined uniformly by the telephone management server 1042 and 1065 by exchanging information by the said IP communication means, and confirms previously that it is the same value separately.

When the table management server 1043 informs the network node apparatus 1031 of the above four addresses (step A108), the network node apparatus displays the first record of the address management table 1034 inside the network node apparatus as shown in FIG. As a result, the four addresses " EA1, EA2, IA1, IA2 " are held (step A109). The first row of the address management table 1034 is defined as an IP communication record between the media router 1021 having the external IP address "EA1" and the media router 1022 having the external IP address "EA2". The IP communication record provides the address information in the IP header in the IP encapsulation that generates the internal IP packet. Likewise, as the second row record of the address management table 1034, four addresses "EA1, EA3, IA1, IA3" are set as IP communication records.

In the same manner, the user 1062 applies the telephone service to the telephone receiver 1063 and goes through the same procedure as described above (steps A110 to A119 in FIG. 99), and is shown in FIG. 101 inside the network node device 1032. As described above, an IP communication record between the media router 1022 having the external IP address "EA2" and the media router 1021 having the external IP address "EA1" is set, and the first to fourth rows of the address management table 1035 are set. By the same principle as described above in the record, an IP communication record or another IP communication record between the media router 1022 having the external IP address "EA2" and the media router 1023 having the external IP address "EA3" is set. have. Further, instead of the above procedure in which the user 1062 applies to the telephone receiver 1063 to set an IP communication record between the media router 1022 and the media router 1021, the user 1060 applies to the telephone receiver 1061. It is also possible to set up an IP communication record between the media router 1022 and the media router 1021. For this reason, when the telephone management server 1042 performs step "A107", step "A117-2" (FIG. 99) is also performed at the same time and requests the table management server 1066 to set an IP communication record.

<< connection phase >>

The user picks up the handset of the telephone 1011 and dials and enters the telephone number " Tel-No-2 " of the communication counterpart telephone 1012, and makes a telephone call to the media router management unit 1056 inside the media router 1021 ( In step A200 of FIG. 102, the media router manager 1056 confirms the telephone call (step A 201).

The media router management unit 1056 presents the telephone number "Tel-No-2" to the telephone number server 1026 (step A202), obtains the IP address "EA2" of the corresponding media router 1022 (step A203). ), Source telephone number "Tel-No-1", destination telephone number "Tel-No-2", telephone call identifier "C-ID", and connection control information "Info-1" An external IP packet 1070 (FIG. 103) for telephone call setting including " " is formed and transmitted to the network node apparatus 1031 (step A204). Here, the IP address area of the IP header of the external IP packet 1070 is a source IP address "EA1" and a destination IP address "EA2", and the payload portion of the external IP packet 1070 is a UDP segment, and a source port number. Is an example in which "5060" is set and the destination port number is "5060". The telephone call identifier " C-ID " is used to distinguish the telephone call from the connection phase after the origination of the telephone call in the telephone communication to the voice communication phase and the release phase from other telephone calls. The access control related information " Info-1 " includes at least a UDP port number used in the voice communication phase, for example, " 5004 " IP address "EA1" of 1021) may be included. Here, the media router managers 1056 and 1057 set and refer to the telephone call identifier "C-ID" and the connection control related information "Info-1" according to a predetermined rule.

When the network node device 1031 receives the IP packet 1070, the internal IP address assigned to the end portion (logical terminal) of the communication line 1040 in which the IP packet 1070 is inputted is "IA1" and the IP packet. It is confirmed that the destination external IP address at 1070 is "EA2", and the address management table 1034 shown in FIG. 100 is searched. First, an IP communication record whose source internal IP address is " IA1 " is searched, and then there is an IP communication record whose destination external IP address includes " EA2 " in the detected IP communication record.

Next, it is checked whether "EA1" is included as a source external IP address in the IP packet 1070 in the detected IP communication record. In this case, when an IP communication record of the first line from the top of the address management table 1034, that is, "EAI, EA2, IA1, IA2" is found, "IA1" described in the third and fourth inside the IP communication record is found. And an IP packet encapsulation technique for giving a new IP header to the external IP packet 1070 using " IA2 " to form the internal IP packet 1071 shown in FIG.

In the search of the IP communication record in the above-described address management table, a record in which the source IP address of the source is " IA1 " Search for IP communication records with " EA2 " Search for the source external IP address " EA1 " may be omitted. In the encapsulation of the IP packet, a source IP address " IA1 " and a destination IP address " IA2 " of the internal IP address are set in the IP address area of the header portion of the internal IP packet. The formed internal IP packet 1071 is transmitted to the network node apparatus 1032 (step A205), reaches the network node apparatus 1032 via the routers 1035-1 to 1035-6, and the network node apparatus 1032 ) Decapsulates the IP packet except for the header of the IP packet 1071 to restore the IP packet 1072 (FIG. 105), and transmits the IP packet 1072 to the media router 1022 (step A206). .

In decapsulation of the IP packet, the network node device 1032 may use an IP communication record having a value of "EA2, EA1, IA2, IA1" as follows. That is, an IP communication record including the four IP addresses exists in the address management table 1035 inside the network node device 1032, and " IA2, IA1 in the IP address area inside the received internal IP packet 1071 header. And "EA2, EA1" exists in the IP address area inside the external IP packet 1072, thereby confirming that decapsulation is possible. When there is no IP communication record that matches four addresses ("EA2, EA1, IA2, IA1"), the received IP packet may be discarded. Alternatively, when there is no IP communication record in which three addresses ("EA1, IA2, IA1") match in the address management table 1035, the destination external IP address "EA2" in the IP packet 1071 is not checked. The received IP packet may be discarded without decapsulation.

The media router management unit 1057 connects the source telephone number "Tel-No-1", the destination telephone number "Tel-No-2", the telephone call identifier "C-ID" from the external IP packet 1072, and the connection. Obtains control related information "Info-1". The media router management unit 1057 acquires, for example, "5004" from the inside of "Info-1" as the port number used by the sender's telephone in the voice communication phase, and uses the telephone call identifier "C-ID" to obtain the port number. Incoming phone calls can be used to distinguish them from other phone calls.

A series of steps A204, A205, and A206 described above are called call setups, and the series of steps are omitted by " IAM ".

The media router management unit 1057 informs the call setup of the call setup acceptance by the telephone call identifier "C-ID", the source telephone number "Tel-No-1", and the destination telephone number "Tel-No-2". IP packets containing "" are returned to the media router management unit 1056 (steps A207, A208, and A209). This series of steps A207, A208, and A209 are called call setup acceptance and are denoted by "ACM" as abbreviations. The media router management unit 1057 uses only the telephone call identifier "C-ID" in the call setting reception and does not return the source telephone number "Tel-No-1" and the destination telephone number "Tel-No-2". It may be.

Next, when the media router management unit 1057 forwards the telephone call (incoming call) to the telephone 1012 (step A210), the telephone 1012 returns to confirm the incoming call (step A211) and sounds a telephone ring tone. The media router management unit 1057 notifies that the telephone 1012 is being called, the telephone call identifier "C-ID", the source telephone number "Tel-No-1", and the destination telephone number "Tel-No-2". Generates an IP packet including the IP packet and returns to the media router management unit 1056 (steps A212, A213, A214). This series of steps A212, A213 and A214 are called call passing or in call and are denoted by "CPG" as an ellipsis. In the call passing step, it is also possible not to return the source telephone number "Tel-No-1" and the destination telephone number "Tel-No-2". The media router management unit 1056 notifies the source telephone 1011 that the destination telephone 1012 is being called (step A215).

On the other hand, when the user of the telephone 1012 hears a telephone ring tone and raises the telephone handset to notify the media router management unit 1057 (step A220), the media router management unit 1057 indicates the telephone call identifier "C-ID" described above, and the source telephone number. Media router management unit 1056 inside the media router 1021 by generating an IP packet including "Tel-No-1", destination telephone number "Tel-No-2", and access control related information "Info-2". (Steps A222, A223, A224). This series of steps A222, A223, and A224 are called responses, and are denoted by "ANM" as abbreviations. The connection control related information "Info-2" includes at least the UDP port number used in the voice communication phase, for example, "5006". The IP packet has the same format as the internal IP packet 1071 of FIG. 104, but the source telephone number " Tel-No-1 " and the destination telephone number " Tel-No-2 " You may. The media router manager 1056 confirms the response (step A220) of the telephone 1012 (step A221).

The media router management unit 1056 knows, for example, "5006" of the destination port number used in the communication phase from "Info-2" and informs the telephone 1011 of the response (off-hook) from the telephone 1012. (Step A225), the telephone 1011 confirms this (step A226). In addition, the said step A221 and the step A226 can also be abbreviate | omitted. The connection phase of telephone call is completed by the above.

In addition, among the above steps, "call setting" in steps A200 and A210, "call setting acceptance" in steps A201 and A211, "call" in step A215, "response" in steps A220 and A225, and "response confirmation in steps A221 and A226." Are called. "

<< communication phase >>

When the user of the telephone 1011 starts a conversation by voice, a voice signal is sent to the media router manager 1056 (step A250 in FIG. 106), and the media router manager 1056 digitizes the voice and has an appropriate length. Separately, the external IP packet 1073 of FIG. 107 is formed. The digitized voice is stored in the payload portion of the UDP segment inside the external IP packet 1073, and the IP packet 1073 is transmitted to the network node device 1031 (step A251). As the source port number in the UDP segment, the source port number "5004" and the destination port number "5006" acquired by the media router management units 1056 and 1057 exchanged with each other in the connection phase are used.

When the network node apparatus 1031 receives the IP packet 1073, it finds an IP communication record of "EA1, EA2, IA1, IA2" in the address management table, and uses the IP communication record to external IP packet 1073. This encapsulation results in an internal IP packet 1074, and reaches the network node apparatus 1032 through the routers 1035-1 to 1035-6 (step A252). Then, the external IP packet 1075 is restored, and the external IP packet 1075 is sent to the telephone 1012 via the media router management unit 1057 (step A253) (step A254). The IP packet including the voice of the telephone 1012 user flows in the opposite direction to the above description, that is, the media router management unit 1057 (step A260), the network node device 1032 (step A261), and the routers 1035-6 to The network node apparatus 1031 is reached through 1035-1 (step A262), and is sent to the telephone 1011 via the media router management unit 1056 (step A263) (step A264).

<< liberation phase >>

When the user of the telephone 1011 puts the handset to end telephony and notifies the media router management unit 1056 of the end of the telephony communication (step A280 in FIG. 110), the media router management unit 1056 means at least the telephony end. Form an IP packet including the information and the telephone call identifier "C-ID". This IP packet is transmitted to the network node apparatus 1031 (step A281), encapsulated in the network node apparatus 1031, passed through the IP transmission network 1003, and reached the network node apparatus 1032 (step A282). It is decapsulated in the node apparatus 1032 and reaches the telephone 1012 via the media router management unit 1057 (step A283) (step A 284). This series of steps A281, A282, A283, and A284 are called releases and are denoted by "REL" as abbreviations.

Next, IP packets reporting release completion are notified in the reverse direction (steps A286, A287, A288). This series of steps A286, A287, and A288 are called releasing completion, and are denoted by "RLC" as abbreviations. The format of the IP packet used in steps A281, A282, A283, and the like, and the method of setting the IP address are the same as in steps A204, A205, A206, etc. in the telephony connection phase.

<< communication between different phones >>

It is likewise possible to make a telephone communication from the telephone 1011 to the telephone 1013 having the telephone number "Tel-No-3", and if the telephone number server 1026 asks a question, the telephone number "Tel-No-3" corresponds to the telephone number "Tel-No-3". The external IP address "EA3" is returned. IP communication records "EA1, EA3, IA1, IA3" in the address management table 1034 and IP communication records "EA3, EA1, IA3, IA1" in the address management table 1035 are used for encapsulation or decapsulation of IP packets. . It is also possible to carry out telephone communication from the telephone 1012 to the telephone 1013 by the same method for controlling the communication connection between terminals as described above. When the telephony ends, the port numbers "5004" and "5006" are free numbers and can be used for the next telephony.

<< case with one communication company >>

Even when the operation management range 1006 of the communication company 2 of FIG. 98 does not exist and the IP telephone network 1003 becomes the operation management range of the communication company 1, the connection phase, the call phase, and the release phase of the telephone call are possible. . In this case, the operation management range 1006 of the communication company 2 is changed to the operation management range of the communication company 1, thereby removing the representative server 1 of the communication company 1 and the representative servers 1036-1 to 1036-2 of the communication company 2, The router 1035-7 and the router 1035-1 are connected by an IP communication line.

<< Other Embodiments of Media Router >>

Another embodiment of a media router will be described with reference to FIG. 111. The media router 1021-1 includes the functions of the media router 1021 shown in FIG. 98, the media router management unit 1056-1 includes the functions of the media router management unit 1056, and the telephone number server 1022-10. 1) includes the functions of phone number server 1026, respectively. Reference numeral 1040-1 denotes a communication line to the network node device. Reference numeral 1080-1 denotes a connection control unit, reference numeral 1081-1 denotes a telephone control unit, reference numeral 1082 denotes a media router operation management unit, and reference numeral 1083 denotes a correspondence table of telephone numbers, pin numbers, and UDP port numbers. The media router operation management unit 1082 includes a function of recording a telephone call and a reliability management function by detecting a failure inside the media router. The telephone control unit 1081-1 is connected to the telephones 1011-1 to 1011-4 via a communication line, and includes protocol conversion, voice code conversion, shake control, analog voice to digital voice in telephone communication, or It has the function to transmit and receive by inverse transformation. Reference numeral 1084 denotes a line interface unit and includes a function for transmitting and receiving a communication line 1040-1 and an IP packet. The media router operation management unit 1056-1 may perform dial-up control and release control equivalent to the media router operation management unit 1056, that is, the dial-up control described with reference to FIG. 102 and the phone release control described with reference to FIG. 110. .

The telephone number, the pin number, and the UDP port number correspondence table 1083 correspond to the telephone number "Tel-No-1" 1: 1 in the pin number "T1" in the telephone control unit 1081-1, and the pin number "T1". To UDP port number " 5004 " The following is the same, the telephone number "Tel-No-12" corresponds 1: 1 with the pin number "T2" and the UDP port number "5006", and the telephone number "Tel-No-13" corresponds to the pin number "T3" and UDP. 1: 1 corresponds to the port number "5008", and the phone number "Tel-No-14" indicates 1: 1 correspondence to the pin number "T4" and the UDP port number "5010". In this case, for example, in the case of using the telephone number "Tel-No-1", the UDP port number is referred to as "5004" with reference to the telephone number, pin number, and UDP port number correspondence table 1083. The UDP port number is used as a port number (RTP port number for voice communication) that identifies a known RTP for voice communication.

1083-1 in FIG. 112 shows another embodiment of the telephone number, pin number, and UDP port number correspondence table, and can be replaced with 1083. FIG. In this case, the telephone number "Tel-No-1" is the representative telephone number and the telephones 1011-1 to 1011-4 have the same telephone number "Tel-No-1" and the UDP port numbers are "5004" to "5010. &Quot;, the telephones 1011-1 to 1011-4 are capable of voice communication of the telephone using different port numbers without being confused at the same time.

1083-2 of FIG. 113 shows another embodiment of the telephone number, pin number, and UDP port number correspondence table, which can be replaced with the corresponding table 1083. FIG. In this case, the telephone 1011-2 having the telephone number " Tel-No-12 " calls the previous time and is given the UDP port number " 5004 ". The other telephones 1011-1, 1011-3, and 1011-4 are given different unassigned UDP port numbers " 5006 " and " 5008 " and the like at the stage of the connection phase initiating telephony, and the release phase of the telephone call. The assignment of the UDP port number assigned by the is stopped (returned). The connection control unit 1080-1 can realize the representative telephone number as described above by appropriately changing the corresponding combination of the pin number and the UDP port number.

<< Other Embodiments of Media Router >>

Another embodiment of a media router will be described with reference to FIG. 114. The media router 1021-2 includes the functions of the media router 1021 shown in FIG. 98, and the connection control unit 1080-2 includes the functions of the connection control unit 1080-1 shown in FIG. 1081-2 includes the functions of the telephone control unit 1081-1. Reference numeral 1040-2 denotes a communication line for connecting to the network node device. The media router manager 1056-2 includes the functions of the media router manager 1056, and the phone number server 1026-2 includes the functions of the phone number server 1026. Reference numeral 1085-1 denotes a PBX control unit, reference numerals 1085-2 denotes a PBX, reference numerals 1086 and 1087 denote routers, reference numeral 1088 denotes an operation management unit of a media router, reference numeral 1089 denotes a communication line using Ethernet, and reference numerals 1090 and 1091. Denotes an IP terminal having a function of transmitting and receiving an IP packet, and reference numeral 1092 denotes a moving image transceiver having a function of transmitting and receiving an audio image. The IP terminals 1090 and 1091 and the moving picture transceiver 1092 are both connected to the router 1087 via an IP communication line. The router 1087 is also connected to the LAN 1093 via an IP communication line. The connection control unit 1080-2, the telephone number server 1026-2, and the routers 1086 and 1087 are connected to each other by the communication line 1089.

The PBX 1085-2 is a private branch exchange that accommodates a plurality of telephones, and the PBX control unit 1085-1 is located between the connection control unit 1080-2 and the PBX 1085-2 and converts both interfaces ( Voice code conversion, voice compression, or the like). As such, the media router 1021-2 can accommodate multiple telephones directly through the telephone control unit 1081-2 or through the PBX 1085-2. These phones can communicate with other phones via an IP transport network.

Since the media router 1021-2 is configured as described above, the IP packet input from the communication line 1040-2 reaches the connection control unit 1080-2 through the router 1086 and the communication line 1089. The IP packet can be transmitted in the reverse direction, that is, from the connection control unit 1080-2 toward the communication line 1089, the router 1086, and the communication line 1040-2. Similarly, the IP packet inputted from the communication line 1040-2 passes through the router 1086, the communication line 1089, the router 1087, the communication line, and the IP terminal 1090 or the IP terminal (inside the LAN 1093). 1091, the moving picture transceiver 1092 can be reached anywhere. In addition, IP packets can be transmitted in the reverse direction, and a communication line, a router 1087, a communication line 1089, a router 1086, and a communication line are provided from the IP terminal 1090, the IP terminal 1091, and the moving picture transceiver 1092. It is possible to transmit to (1040-2).

<< outgoing priority (priority) control >>

Next, the function of the transmission priority (priority) control of the media router 1021-2 will be described. FIG. 115 is a schematic diagram showing a connection state between a part of the inside of the media router 1021-2 and an IP terminal or a LAN connected to the media router 1021-2. However, the description of the communication line in the figure is omitted, reference numerals 1085-21 denote IP packets transmitted from the telephone number server 1026-2, and reference numerals 1085-22 denote IP packets transmitted from the connection control unit 1080-2. 1085-23 denotes an IP packet transmitted from the LAN 1093, 1085-24 denotes an IP packet transmitted from the IP terminal 1091, and 1085-25 denotes an IP packet transmitted from the moving picture transceiver 1092. to be. IP packets 1085-21 to 1085-25 are sent to the communication line 1040-2 via the Ethernet communication line 1089 and the router 1086. When the payload of the IP packets 1085-21 to 1085-25 is a TCP or UDP segment, the source port number and the destination port number are included inside these segments.

Reference numeral 1085-3 in FIG. 116 denotes an outgoing priority (priority) control management table 1085-3 which determines the order in which the IP packet is sent from the Ethernet communication line 1089 side to the communication line 1040-2. have. When an IP packet is input from the Ethernet communication line 1089 side and passes through the router 1086 and output to the communication line 1040-2, it is examined whether the payload inside the passing IP packet is a TCP segment or a UDP segment. If it is a TCP segment or a UDP segment, check the source port number inside it. When the IP packet arrives at the router 1086 at an approximate time, an IP packet containing a TCP segment or a UDP segment with a source port number of "108" is sent first in time, and then the source port number is IP packets containing TCP segments or UDP segments of "5060" or "5004" to "5020" are sent.

The port number described in the calling priority order control administration table 1085-3 may be changed to another value and used. It is also possible to change the originating priority management table 1085-3 to the originating priority control management table 1085-4 in FIG. In the case of using the outgoing priority control management table 1085-4, the IP packet having a source IP address of "150.1.2.3" and a source port number of "108" is given priority, and the source IP address "192.1 as the next priority. .2.3 ", and an IP packet having a source port number" 5060 "or" 5004 "to" 5020 "is given priority.

In the above embodiment, the media router 1021-2 is based on the port number specified by the outgoing priority control management table 1085-3, or the IP specified by the outgoing priority control management table 1085-4. It is characterized by having a function of determining the transmission order of IP packets sent from the IP packets to the communication line 1040-2 based on the set of addresses and port numbers.

Next, a description will be given with reference to FIG. The media routers 1021-3 and 1021-4 are connected via the IP transport network 1001-1, and the IP terminal 101-1-1, the video transceiver 1092-1, and the LAN are connected to the media router 1021-3. 1093-1 is connected, and IP terminal 1090-1 is included in LAN 1093-1. Similarly, an IP terminal 1091-2, a moving picture transceiver 1092-2, and a LAN 1093-2 are connected to the media router 1021-4, and the IP terminal 1090-2 is inside the LAN 1093-2. ) Is included. Media routers 1021-3 and 1021-4 include the functions of the media routers 1021-2 of FIG. 114. By such a configuration, for example, between the IP terminal 1090-1 and the IP terminal 1091-2, between the IP terminal 1011-1 and the IP terminal 1090-2, the moving picture transceiver 1092-1 is provided. IP packets can be transmitted and received between the video transceiver 1021-2 and the video router 1021-3, the IP transmission network 1001-1, and the media router 1021-4.

The above is summarized as follows. The IP transport network includes two or more network node devices, and the media router is connected to any one of the network node devices via an IP communication line, and an internal IP address is assigned to a network node device side end of the IP communication line. Each media router is provided with an external IP address, and has a telephone number server inside, and the media router is connected to one or more telephones via a communication line. In addition, an IP communication record that includes the external IP address and the internal IP address as a record of an address management table inside the network node device, and at least determines an IP encapsulation method, is set in advance, and at least the source telephone in the call setup IP packet. The number, destination telephone number, and connection control use a common port number for a plurality of telephones, and individual voice communication for each telephone assigns a different port number for each telephone, so that the media router can be configured as either a PBX controller or a telephone controller. The media router may include an IP terminal or LAN having a function of transmitting and receiving an IP packet, and a voice image transceiver having a function of storing and transmitting an audio image in an IP packet and transmitting the IP packet through an IP communication line. The media router uses the source port number of the TCP segment or the UDP segment in the IP packet sent to the media router from a telephone, an IP terminal, a video transceiver, or the like connected to the media router, including a source priority control management table, and a source IP address. According to the designation of the originating priority control management table, the transmission can be sent to the network node device side communication line in the order of high priority.

9. Ninth Embodiment of Closed Area Telephone Communication:

In FIG. 119, reference numeral 1100 denotes an IP transmission network, and an IP address used outside the IP transmission network 1100 is called an external IP address, and an IP address used internally is called an internal IP address. The media routers 1115 to 1117 are assigned external IP addresses "EA1" to "EA3", respectively. The telephones 1121 to 1124 are assigned telephone numbers "101", "102", "103", "104", and the telephones 1125 to 1128 are telephone numbers "211", "212", "213", " 214 ", and telephone numbers 1301 to 1132 are assigned telephone numbers" 301 "," 302 "," 303 ", and" 304 ".

The telephone number servers 1135 to 1137 have the same function as a domain name server (DNS) widely used in the Internet. In the present embodiment, the telephone number server 1135 to 1137 is provided outside of the media router accommodating the telephone having the telephone number. Answer the IP address. For example, when the telephone number server 1135 asks the telephone number "212", it returns the external IP address "EA2" of the media router 1116 containing the telephone 1126 having the telephone number "212".

<< Preparing for Telephony >>

In the network node apparatus 1101 to 1103, IP communication records are set as records of the internal address management tables 1110 to 1112, respectively. For example, as the second line IP communication record of the address management table 1110, "EA1, EA3, IA1, IA3" is set, and the IP communication record has a media router 1115 having an external IP address "EA1". It is used for telephone communication between the media routers 1117 having the external IP address "EA3". The internal IP address " IA1 " is assigned to the network node device 1101 side end portion (logical terminal) of the logical IP communication line 1144, and the internal IP address " IA3 " is the network node device of the logical IP communication line 1146. It is provided to the end part of the (1103) side. The "terminal communication connection control method" for carrying out telephone communication from the telephone 1121 to the telephone 1113 via the media router 1115, the IP transmission network 1100, and the media router 1117 will be described.

<< connection phase >>

The user picks up the handset of the telephone 1121, dials and enters the telephone number "303" of the communication counterpart phone 113, and passes the telephone control unit 1133 to call the media router management unit 1138 inside the media router 1115. (telephone call) (step A300 in Fig. 120), the media router management unit 1138 confirms the telephone call (step A301). The media router management unit 1138 presents the telephone number "303" to the telephone number server 1135 (step A302), obtains the IP address "EA3" of the media router 1117 (step A303), and then the source telephone. An external IP packet 1134 (see Fig. 119) is formed that includes the number " 101 ", the destination telephone number " 303 ", the telephone call identifier " C-ID " and the UDP port number " 5004 " It transmits to the network node device 1101 (step A304).

Here, the IP address area in the IP header of the external IP packet 1134 is a source IP address "EA1" and a destination IP address "EA3", and the payload portion of the external IP packet 1134 is a UDP segment, and a source port number. The example assumes "5060" and the destination port number "5060".

When the network node device 1101 receives the IP packet 1134, the network node apparatus 1101 uses an IP communication record, which is the second line above the address management table 1110, that is, "EA1, EA3, IA1, IA3", to encapsulate the IP packet. An internal IP packet 1140 is formed and transmitted toward the network node device 1103 (step A305). The internal IP packet 1140 arrives at the network node device 1103 via the routers 1105, 1106, and 1107, and the network node device 1103 decapsulates the IP packet except for the header of the IP packet, thereby performing an IP packet. 1134, the IP packet 1134 is transmitted to the media router management unit 1117 (step A306). This series of steps A304, A305, and A306 are called call setting operations and are denoted by "IAM" as abbreviations.

From the received IP packet, the media router management unit 1139, the source telephone number "101", the destination telephone number "303", the IP address "EA1" of the media router 1115, and the telephone call identifier "C-ID". &Quot; " UDP port number " 5004 " used by the sender's telephone in the voice communication phase as the connection control related information, and a confirmation of the telephone call is returned (steps A307, A308, A309). This series of steps A307, A308, and A309 are called call setting acceptance and are simply referred to as "ACM". Next, the media router management unit 1139 sends an IP packet informing the telephone call (incoming) to the telephone 1131 (step A310), and the telephone 1131 returns (step A311). The telephone 1131 sounds a telephone ring tone when it knows the telephone call. When the media router management unit 1139 returns to the media router management unit 1138 that the telephone 1113 is being called (steps A312, A313, and A314), the media router management unit 1138 sends a destination address to the source telephone 1121. The telephone 1131 is notified that the telephone is being called (step A315). This series of steps A312, A313, and A314 are referred to as call passing or being called, and are simply referred to as "CPG".

When the user of the telephone 1131 raises the handset of the telephone (off-hook), it is notified to the media router management unit 1139 (step A320), and the media router management unit 1139 returns (step A321: acknowledgment of the response). The router management unit 1139 includes a source telephone number "101", a destination telephone number "303", a telephone call identifier "C-ID", and a UDP port that the telephone 1113 uses in the voice communication phase as connection control related information. An IP packet including the number "5008" is formed and returned to the media router management unit 1138 (steps A322, A323, and A324). The media router manager 1138 knows the UDP port number " 5008 " used by the destination telephone from the received information. The media router management unit 1138 notifies the telephone 1121 of the off-hook notification from the telephone 1113 (step A325), and the telephone 1121 returns (step A326: response confirmation). The series of steps A322, A323, and A324 are called responses, and are simply referred to as "ANM". The response confirmation steps A321 and A326 are options for selecting whether or not to perform them. The telephone connection phase is completed by the above.

<< communication phase >>

When the user of the telephone 1121 starts a conversation by voice, the voice signal is sent to the media router management unit 1138 (step A350 in FIG. 120), and the media router management unit 1138 is digitized by the telephone control unit 1133. The voice is stored in the payload portion of the UDP segment in the IP packet and then transmitted to the network node device 1101 (step A351). As the source port number in the UDP segment, a source port number "5004" and a destination port number "5008" obtained in the connection phase are used.

When the network node device 1101 receives the IP packet including the digitized voice, the network node device 1101 encapsulates it into an internal IP packet 1141, and the internal IP packet 1141 passes through the routers 1105, 1106, and 1107. 1103 is reached (step A352). The network node device 1103 performs IP de-encapsulation excluding the internal IP header of the internal IP packet 1141, transmits the obtained external IP packet to the media router management unit 1139 (step A353), and sends it to the telephone 1113. (Step A354). The IP packet containing the digitized voice of the user of the telephone 1131 is sent to the telephone 1121 via the above reverse flow (steps A360 to A364).

<< release phase >>

When the user of the telephone 1121 notifies the end of the telephone communication (step A380 in Fig. 120), the telephone 1113 is reached through the same series of steps (steps A381 to A383) described in the other embodiments (step A384). This telephony end report is returned to the media router management unit 1138 in steps A386 to A388. The series of steps A380, A381, A382, A383, and A384 are referred to as release and are simply referred to as "REL". In addition, another series of steps A386, A387, and A388 are referred to as release completion, and are simply referred to as "RLC".

Communication between other telephones, for example, telephone 1127 having telephone number "212" from telephone 1121 and telephone 1127 having telephone number "213" from telephone 1132. Telephone communication is possible by the same terminal-to-terminal communication connection control method as described above.

<< Detailed Description of Phone Number Server >>

The function of the telephone number server will be described in more detail. Considering that the number 100 of the phone number is connected to the media router 1115, the number 200 of the phone number is connected to the media router 1116, and the number 300 of the phone number is connected to the media router 1117, respectively. As shown in FIG. 121, the tree structure of the telephone number can be determined. Under the root 1150, the domains 1151 to 1153 may be associated in the same level of tree structure. Domain 1151 provides information about 100 phone numbers, domain 1152 provides information about 200 phone numbers, and domain 1153 provides information about 300 phone numbers. 100 telephone numbers are represented as "1." as domain names, 200 telephone numbers are represented as "2." as domain names, and 300 telephone numbers are defined as "3." as domain names. This is summarized in FIG. 122. In Fig. 122, "1XX" represents 100 telephone numbers, "2XX" represents 200 telephone numbers, and "3XX" represents 300 telephone numbers, respectively.

In addition, the telephone number server 1135 may give a function to substitute for the function of the telephone number server managing the route 1150 by applying a known technique for the domain name server DNS. By the function of the telephone number server managing the route 1150, when asked "1.", the IP address "EA1" of the telephone number server 1135 directly managing the domain 1151 is returned, and "2." And "3." answer "EA2" and "EA3", respectively. When the telephone number server is asked for a domain name that each directly manages, the telephone number server may return the IP address of another telephone number server in the course of elapsed time, but finally the IP address corresponding to the domain name in question is answered (FIG. 123). . In this way, when the telephone number server 1136 asks "3.", the IP address "EA3" corresponding to "3." can be obtained. The concrete realization method of the "recursive call function of the telephone number server" which makes repeated inquiry between such telephone number servers is employ | adopted by employing the recursive call function of a well-known domain name server.

<< Another embodiment of telephone number server >>

As shown in FIG. 124, the media routers 1191 to 1197 are connected to any one of the network node devices 1180 to 1184 of the IP transport network 1190 via a communication line, and the media router 1191 belonging to company A. The telephone number of the telephone to be connected to is the public telephone number " 1-1xx " Here, "-" is ignored because it is equivalent to a space as a telephone number, and "xx" means "00" to "99" in decimal. The telephone number of the telephone to be connected to the media router 1193 belonging to the company A is also a telephone number to be disclosed. The telephone numbers of the telephones connected to the media router 1195 belonging to the company A are the telephone numbers " 1-3 ×× " disclosed to other companies and the extension telephone number " 8 ×× " The telephone number of the telephone connected to the media router 1192 belonging to the company B is a public telephone number "2-1 × x", and the telephone number of the telephone connected to the media router 1194 belonging to the company B is a telephone disclosed. It is number "2-2xx". The telephone number of the telephone connected to the media router 1196 belonging to the company C is a public telephone number "3-xxx". "Xxx" means "000" to "999" in decimal. The telephone number of the telephone connected to the media router 1197 belonging to the company A is the extension telephone number " 7 ×× "

125 is a representation of the above telephone number system as a tree structure of telephone numbers, reference numeral 1185 denotes a root domain, reference numeral 1186 denotes a domain for company A's private extension telephone number, and reference numeral 1187 denotes a company A disclosure. A domain for phone numbers, reference numeral 1188 denotes a domain consisting of telephone numbers disclosed by company B, and reference numeral 1189 denotes a domain targeted for telephone numbers disclosed by company C. Here, the domain name "## " of reference numeral 1186 is a secret domain name used only inside the media routers 1195 and 1197 belonging to company A. It does not include a number and the domain name has a long value of 20 characters. Deciding. In this manner, it is difficult to know the value of the company A dedicated secret domain name "##" or to acquire the domain name "##" from the media routers 1192, 1194, and 1196 of the company B and the company C. For example, the IP address is not returned for the inquiry of "##". As a result, safety is improved in the sense that it is difficult for Company B or Company C to access (access) the telephone having the company A's extension telephone number, making it difficult to use the extension telephone number.

When the destination telephone number "2-145" is dialed from the telephone 1198, the media router management unit 1195-1 in the media router 1195 converts the telephone number "2-145" into the conversion table 1118-FIG. As shown in 1), the phone number is converted to " 1.2. &Quot; Next, if the telephone number server 1195-2 in the media router 1195 is presented with a question of " 1.2. &Quot;, the telephone number server can display " 1.2. IP address " MR2 " of the media router 1192 corresponding to "

Incidentally, whether or not the telephone of the company B having the telephone number "2-100" can be called from the telephone of the company A having the extension telephone number "700" depends on the setting of the domain name server.

Summarizing the above, it becomes as follows. That is, the IP transport network includes two or more network node devices, and the media router is connected to any one of the network node devices via a logical IP communication line, and an internal IP at a network node device side end of the logical IP communication line. Each of the media routers is assigned an external IP address, has a telephone number server inside, and the media router is connected to one or more telephones via a communication line. An IP communication record that includes the external IP address and the internal IP address as a record of an address management table inside the network node device, and at least determines an IP encapsulation method, is pre-set between the network of Company A, Company B, and Company C. By setting a predetermined IP communication record inside the node device, a phone number valid only between company A, company B, and company C ("1- ×××", "2- ×××", "3- ×××") A closed-area telephone communication network can be established.

Calling Company A's telephone number "1-200" from Company A's telephone number "1-100", calling Company B's telephone number "2-100", telephone number "3" A telephone of Company C, which is -100 ", and a telephone of Company A, which has the extension numbers" 700 "and" 800 ", can be telephoned. In addition, telephone communication of company A with extension telephone number "800" can be called from telephone of company A with extension telephone number "700" and telephone of company A with telephone number "1-200" can be used for telephone communication. . It is impossible to call a company A telephone with the extension telephone number "800" from the phone of company B with the telephone number "2-100" as described in "##" above.

If the number of companies is N, we can do as follows. Predetermined company A-1, company A-2,... For example, an IP communication record may be set to allow telephone communication only between company A-Ns (N> 2), so that end-of-life telephone communication may be performed. Moreover, company A-1, company A-2,... A company A-1's telephone, which connects to a valid retirement telephone network between Company AN (N> 2), can communicate with an extension telephone of Company A-1, and a telephone of a company other than Company A-1 The telephone communication with the extension telephone of A-1 can be disabled.

10. Tenth embodiment that uses closed-area telephony and open-area telephony in combination:

In Fig. 128, reference numeral 1200 denotes an IP transmission network, and external IP addresses " EAI " to " EA6 " are assigned to the media routers 1201 to 1206, respectively. The telephone 1208 has a telephone number "1001", the telephone 1209 has a telephone number "1002", the telephone 1210 has a telephone number "101", and the telephone 1211 has a telephone number "102", respectively. 1215 to 1215 are assigned telephone numbers "3001" to "3004", respectively. Telephones 1216-1219 connecting to media router 1202 have telephone numbers " 234-2001 " and " 234-2004 ", respectively.

The telephones 1220 to 1223 are each assigned telephone numbers "2001" to "2004", and the telephones 1224 to 1127 are each assigned telephone numbers "301" to "304". Are assigned telephone numbers "201" to "204", respectively. Here, telephone numbers "1xx", "2xx", and "3xx" are company A extension telephone numbers, and "x" represents the decimal number from 0 to 9. The telephone number "1xxx" is the telephone number of the company A, the telephone number "2xxx" is the telephone number of the company B, and the telephone number "3xxx" is the telephone number of the company C. These three telephone numbers " 1 ××× ", " 2 ××× ", and " 3 ××× " are telephones for constructing a logical abandoned telephone network for telephone communication only between Company A, Company B and Company C. It is a number and is called a closed-area telephone number. The telephone numbers " 234-2001 " to " 234-2004 " are telephone numbers for making phone calls with unspecified parties, and are called open-area telephone numbers.

The telephone number servers 1134, 1272 and 1137 to 1142 have the same function as the Domain Name Server (DNS) used in the Internet, and when a telephone number is provided, the external IP address of the media router accommodating the telephone having the telephone number. Reply. For example, when the telephone number server 1137 asks the telephone number "3001", it answers the external IP address "EA6" of the media router 1206 containing the telephone 1212 having the telephone number "3001".

<< Preparation of end-to-end connection control for telephony communication >>

As shown in FIG. 128, each of the network node devices 1244 to 1248 has address management tables 1250 to 1255, and the same IP communication record as that described in the other embodiments is set. For example, as the first row IP communication record of the address management table 1250, "EA1, EA3, IA1, IA3" is set, and the IP communication record has a media router 1201 having an external IP address "EA1". It is used for telephone communication between the media routers 1203 having the external IP address "EA3". The internal IP address " A1 " is assigned to a network node device 1244 side end portion (logical terminal) of the logical IP communication line 1257, and the internal IP address " IA3 " is the network node device of the logical IP communication line 1258. It is provided to the end part of the (1248) side.

128 and 129 show a "terminal communication connection control method" for performing telephone communication from the telephone 1208 of telephone number "1001" to the telephone 1224 of telephone number "301" via IP transmission network 1200. It will be described with reference to.

<< connection phase >>

Picking up the handset of the telephone 1208 and dialing and entering the telephone number " 301 " of the communication counterpart telephone 1224, the call signal is transmitted to the media router management unit 1260 (step H300), and the media router management unit 1260 calls the telephone. (Step H301). The media router management unit 1260 examines the table 1255-1 in FIG. 175 held therein and finds that the domain name of the telephone number corresponding to the telephone number "301" is "3. #. A", The telephone number server 1137 inquires the telephone number domain name "3. #. A" (step H302), and the telephone number server 1137 uses the media router (FIG. 1255-2) in accordance with the rules shown in the table 1255-2 of FIG. The IP address "EA4" of 1204 is returned (step H303).

Next, an external IP packet 1310 (FIG. 130) is formed which includes at least the source telephone number "1001", the destination telephone number "301", and the UDP port number "5004" used for call transmission of the telephone 1208. The data is transmitted to the network node device 1244 (step H304). The IP packet 1310 may include related information " Info-1 " consisting of identification numbers of telephone calls related to the media router 1260, identification names such as a voice compression scheme, voice code conversion, and the like.

When the network node device 1244 receives the IP packet 1310, the network node device 1244 uses the IP communication record of the second line from the top of the address management table 1250, that is, "EA1, EA4, IA1, IA4". In this way, an internal IP packet 1311 (FIG. 131) is formed and transmitted. The internal IP packet 1311 arrives at the network node device 1246 via the routers 1262 and 1264 shown in FIG. 128 (step H305), and the network node device 1246 decapsulates the IP packet and performs an IP packet. The recovered IP packet is transmitted to the media router 1204 (step H306).

The media router management unit 1265 acquires at least the source telephone number "1001", the destination telephone number "301", and the UDP port number "5004" for the call from the received IP packet, and returns a confirmation of the telephone call (step) H307, H308, H309.

Next, the media router management unit 1265 passes the telephone call (incoming call) to the telephone 1224 (step H310). The telephone 1224 returns to the media router management unit 1265 (step H311), and again sounds a telephone ring tone. The media router management unit 1265 informs the destination telephone 1208 via the media router management unit 1260 that the telephone 1224 is being called (steps H312, H313, H314, H315). In step H314, the phone 1208 is informed of the source telephone number "1001", the destination phone number "301", and the UDP port number "5008" used for call transmission of the phone 1224.

When the user of the telephone 1224 picks up the handset of the telephone, the telephone 1224 notifies the media router management unit 1265 (step H320). The media router manager 1265 responds to the source telephone 1208 via the media router 1260 with the response by step H320 (steps H322, H323, H324, and H325). The telephone 1208 confirms the response toward the media router 1260 (step H321), and the media router 1265 confirms the response toward the telephone 1224 (step H326). Here, step H321 and step H326 are options for selecting whether or not to perform. The telephone connection phase is completed by the above.

In the connection phase, the outer IP packet inside is a UDP segment, and "5060" is used as the sending and receiving UDP port numbers, for example.

<< Communication phase >>

The telephone communication between the user of the telephone 1208 and the telephone 1224 is the same steps as described in the other embodiments, and is the second line IP communication record in the address management table 1250, that is, "EA1, EA4, IA1, IA4". And the first row of IP communication records in the address management table 1253, that is, records of "EA4, EA1, IA4, IA1" are used. Voice is sent from the phone 1208 to the media router management unit 1260 (step H350), and the voice is digitized in the media router management unit 1260 and transferred to the payload portion of the external IP packet 1312 (FIG. 132). Network node device 1244 is reached. After the IP is encapsulated and converted into an internal IP packet 1313 (FIG. 133), it is transmitted inside the IP transport network 1200 to reach the network node device 1246 to be decapsulated and arrive at the media router management unit 1265. (Steps H351 to H353). Here, the digitized voice is converted into analog voice and reaches the telephone 1224 (step H354). The telephone voice in the reverse direction from the telephone 1224 to the telephone 1208 is similarly transmitted (steps H360 to H364). In the call phase, the outer IP packet 1312 is inside a UDP segment, and the UDP port number sent from the phone 1208 is "5004", and the UDP port number received by the phone 1208 is "5008", respectively. Yes.

<< liberation phase >>

When the user of the telephone 1208 notifies the end of the telephone communication (step H380 in Fig. 129), the telephone 1224 is reached through the same series of steps (steps H381 to H383) described in the other embodiments (step H384). The media router management unit 1265 notifies the media router management unit 1260 of the release completion (steps H386 to H388). The format of the external IP packet in the release phase is the same as that of the IP packet 1310 used in the connection phase, the payload portion is a UDP segment, and the send and receive UDP port numbers are, for example, "5060". .

<< Another example of using a phone number server inside a media router >>

When the telephone number " 2001 " of the telephone 1220 belonging to another company which is the communication counterpart is picked up by the handset of the telephone 1208, the media router manager 1260 holds the table 1255-1 held therein. And the domain name of the telephone number corresponding to the telephone number " 2001 " Next, the telephone number server 1137 inquires the telephone number domain name "b.", And the telephone number server 1137 answers the IP address "EA5" of the media router 1205 connected to the telephone 1220. Thereby, telephone communication is possible by the same terminal-to-terminal communication connection control method between the telephone 1208 and the telephone 1220 belonging to different companies.

In the terminal-to-terminal communication connection control method described above, the telephone number servers 1134 and 1272 inside the IP transport network 1200 are not used, and the telephone number server 1137 inside the media router 1201 is used instead. In addition, there is a feature that IP communication records that are already set in the address management tables 1250, 1253, and 1252 are used.

<< How to use telephone number server in IP transport network and create IP communication record to communicate by telephone >>

Referring to Fig. 134, a method for controlling communication between terminals is performed by telephone communication from telephone 1208 with telephone number " 1001 " to telephone 1216 with telephone number " 234-2001 ".

<< connection phase >>

When the handset of the telephone 1208 is picked up, a call signal is transmitted to the media router management unit 1260 (step V0), the media router management unit 1260 confirms the telephone call (step V1), and the media router management unit 1260 has its interior. The table 1255-1 (FIG. 175) held in the table is examined to find that the domain name of the telephone number corresponding to the telephone number "234-2001" is "o.". Next, the telephone number server 1137 is inquired of the telephone number domain name "o." (Step V2), and the telephone number server 1137 accesses the telephone number server 1272 which manages the "o." The external IP address " EA81 " of the surrogate telephone management server 1270 is returned to the media router management unit 1260 (step V3).

Next, the media router management unit 1260 sets the source IP address "EA1" to the media router 1201 and the destination IP address to the acquired IP address "EA81". IP packet 1320 (FIG. 135) including new telephone number " 234-2001 ", UDP port number " 5006 " used for telephone voice communication, and additional information " info-2 " Transmit (step V4). The payload portion of the IP packet 1320 is a UDP packet, and both its source and destination port numbers are " 5060 ". The additional information is information used inside the media router 1260, for example, a voice compression scheme (G.711 or G729A) for using the telephone 1208, voice code conversion, or a number for identifying a call of a telephone. to be. The telephone management server 1271 and the proxy telephone management server 1270 described later are not related to the additional information.

The network node device 1244 uses the internal IP address " IA1 " assigned to the end of the logical communication line 1257 input by the external IP packet 1320 and the destination IP address " EA81 " in the IP packet 1320. The IP communication record in the address management table 1250 of FIG. 128 is retrieved. It is also confirmed that the source IP address " EA1 " in the IP packet 1320 is included in the IP communication record, and in this case, the fourth row from the top of the address management table 1250, that is, "EAI, EA81, IA1, IA81". IP packets 1321 (FIG. 136) are formed by applying an IP packet encapsulation technique using the third and fourth IP addresses described in the in record, that is, "IA1" and "IA81". It sends to the alternative telephone management server 1270 whose address is "IA81" (step V5).

When the proxy telephone management server 1270 receives the IP packet 1321, an IP packet 1322 including the payload portion of the IP packet 1321 and the addresses “EA1, IA1, EA81, and IA81” in the payload portion. (FIG. 137), it transmits to telephone management server 1271 (step V6). The alternative telephone management server 1270 uses the IP address " IA91 " of the telephone management server 1271 held in advance.

<< Control of the number of outgoing lines >>

The telephone management server 1271 fetches the address " EAI " of the source media router 1201 from the received IP packet 1322, and compares it with the outgoing line management table 1326-5 in Fig. 160, and the IP address is " EA1 " The number of lines in use for the record of "" is increased by "1" and compared with the upper limit lines. In this embodiment, since the number of lines in use is "2" and the upper limit is "5", the procedure goes to the next procedure. If the number of lines in use is greater than the upper limit, the telephone management server 1271 stops the process without proceeding to the subsequent connection phase. Alternatively, an IP packet describing the reason for the interruption is formed and notified to the source media router management unit 1260 past the proxy telephone server 1270. The telephone management server 1271 can select whether or not to perform outgoing line control.

<< Management of line number >>

The telephone management server 1271 reads the IP packet 1322 (FIG. 137) to obtain the source telephone number "1001" and the destination telephone number "234-2001", and the line for voice communication from the set of these two telephone numbers. The line number "CIC-2" for managing the network is calculated (CIC: Circuit Identification Code). Next, the line number "CIC-2", the source telephone number "1001", the destination telephone number "234-2001", and the telephone 1208 are connected to the record of the CIC management table 1323 (FIG. 138). The external IP address " EA1 " and the internal IP address " IA1 " of the media router 1201, the external IP address " EA81 " and the internal IP address " IA81 " of the telephone agent server 1270, and the telephone agent server 1271. The IP address " IA91 ", the sequence division " IAM ", and the writing time (year, month, day, hour, minute, and second) are written.

Next, the telephone management server 1271 shows the IP number 1324 (FIG. 139) to the telephone number server 1272 that asks the IP address related to the destination telephone number "234-2001" (step V7). The telephone number server 1272 includes the external IP address " EA2 " and the internal IP address " IA2 " of the media router 1202 to which the telephone 1216 is connected, and the external IP address " EA82 " and the internal of the telephone agent server 1275. IP packet 1325 (FIG. 140) containing IP address "IA82" and IP address "IA92" of telephone management server 1274 returns to telephone management server 1271 (step V8). The telephone management server 1271 adds five IP addresses "EA2", "IA2", "EA82", "IA82", and "IA92" obtained from the telephone number server 1272 to the CIC management table 1323 (FIG. 138). The result is shown in the IP address column of the second record of the CIC management table 1326-1 (FIG. 141).

Next, the telephone management server 1271 refers to the IP packet 1327 (see FIG. 142) from the packet 1322 (FIG. 137) with reference to the IP address information of the CIC management table 1326-1 (FIG. 141). And the IP packet 1327 is transmitted to the telephone management server 1274 (step V9). Here, the source IP address of the IP packet 1327 is the telephone management server "IA91", and the destination IP address is the telephone management server 1274 "IA92". The telephone management server 1271 shifts to the standby state of step V16 described later, and starts the step V16 wait timer corresponding to the line number "CIC-2". When this timer has expired, the same procedure as the release of the call line is started as in step V60 described later.

<< Control of the number of incoming lines >>

The telephone management server 1274 fetches the address " EA2 " of the destination media router 1202 (FIG. 161) from the received IP packet 1327 (FIG. 142) and compares it with the terminating line management table 1326-6. The number of lines in use is increased by " 1 " to compare with the upper limit lines. In this embodiment, since the number of lines in use for the record of address "EA2" is "2" and the upper limit number of lines is "7", the procedure goes to the next procedure. The telephone management server 1274 can select whether or not to perform incoming line control using the incoming line management table 1326-6.

<< Management of line number >>

When the telephone management server 1274 receives the IP packet 1327, the line number "CIC-2" included in the payload portion, the order classification "IAM", the source telephone number "1001", and the destination telephone number "234". -2001 ", IP addresses (" EA1 "," IA1 "," EA81 "," IA8I "," IA91 "," EA2 "," IA2 "," EA82 "," IA82 "," IA92 ") It writes and records as a record of CIC management table 1326-2 (FIG. 143) which the telephone management server 1274 manages. This writing time "St-3" is also written in the record of the CIC management table 1326-2.

Subsequently, the telephone management server 1274 forms an IP packet 1328 (FIG. 144) using the information obtained from the IP packet 1327, and transmits it to the alternative telephone management server 1275 (step V10). The payload of the IP packet 1328 includes a UDP segment and an address area, and adds the IP address " EA1 " of the source media router 1201 inside the UDP segment. The address area includes IP addresses "EA2, IA2, EA82, IA82".

The proxy telephone management server 1275 forms the IP packet 1327 (FIG. 145) using the information acquired from the IP packet 1328, and transmits it to the network node apparatus 1247. FIG. The IP packet 1329 with the source address "IA82" and the destination address "IA2" arrives at the network node device 1247 (step V11), and the network node device 1247 decapsulates the received IP packet 1329. After the IP packet 1330 (FIG. 146) is formed, the IP packet 1330 is transmitted to the media router management unit 1267 (step V12).

The media router management unit 1267 receives the IP packet 1330, checks whether the destination telephone number "234-2001" included therein is reachable, and if the call is possible, calls the telephone 1216. call reception) ”(step V20). Further, the contents of the IP packet 1330 are read, that is, the source telephone number "1001", the destination telephone number "234-2001", the source IP address "EA1", the source UDP port number "5006", and additional information Info-2. To hold. The media router management unit 1267 is an IP packet including the source telephone number "1001", the destination telephone number "234-2001", and the likelihood of forwarding to inform the telephone 1216 of the possibility of being able to receive the call (dividing a callable or impossible). Is generated and notified to the telephone management server 1274 (steps V13, V14, V15). In addition, the format of the IP packet used in step V13, V14, V15 is the same as that of the IP packet used in step V22, V23, V24 mentioned later.

The telephone management server 1274 receives the IP packet formed and transmitted by the media router management unit 1267, and transmits a telephone number "1001", a destination telephone number "234-2001", and a call possibility from the received IP packet. Withdraw information. An IP packet 1331 (see Fig. 147, ACM packet) including line number " CIC-2 " is calculated from the two phone numbers and contains callability information of line number " CIC-2 " Is sent to the telephone management server 1271 (step V16). The telephone management server 1271 draws the line number "CIC-2" and the sequence division "ACM" from the received IP packet 1331, and corresponds to the line number "CIC-2" set at the time point of the step V9. Stop the ACM wait timer, examine the CIC management table 1326-1 (FIG. 141) held by the telephone management server 1271, find a record with the line number " CIC-2 " Rewrite in the order division "ACM".

Next, the telephone management server 1271 generates an IP packet indicating that the ACM packet has been received (including the likelihood information of the telephone 1216), and notifies the media router management unit 1260 (steps V17, V18). , V19). The format of the IP packet used in steps V17, VI8, and V19 is the same as that of the IP packet used in steps V26, V27, and V28 described later. Steps V17, V18, and V19 can be selected whether or not to be performed.

When the telephone 1216 reports to the media router management unit 1267 that the telephone call is in progress (step V21), the source telephone number "1001" and the destination telephone number "234-2001" to indicate that the telephone 1216 is on the telephone call. And an IP packet 1332 (FIG. 148) including the UDP port number " 5008 " used by the telephone for voice communication and the additional information Info-3, and transmitted to the network node device 1247 (step V22). The network node device 1247 encapsulates the IP packet 1332 using a record whose address value of the address management table 1254 is "EA2, EA82, IA2, IA82" to encapsulate the IP packet 1332-1 (FIG. 149). Form. The IP packet 1332-1 is sent to the surrogate telephone management server 1275 (step V23), and the surrogate telephone management server 1275 forms an IP packet 1332-2 (FIG. 150) to establish a telephony management server 1274. (Step V24).

The telephone management server 1274 fetches the source telephone number "1001" and the destination telephone number "234-2001" from the received IP packet 1332-2, and the line number "CIC-2" from the two telephone numbers. The IP packet 1333 (refer to FIG. 151, CPG packet) is formed, and it transmits to the telephone management server 1271 (step V25). IP packet 1333 includes UDP port number " 5008 " and additional information Info-3 obtained from IP packet 1332-2.

The telephone management server 1271 withdraws the line number "CIC-2", the sequence division "CPG", the UDP port number "5008", and the additional information Info-3 from the received IP packet 1333, and the CIC management table 1322-6. 1) Rewrite the order division of the record with the line number "CIC-2" (FIG. 141) into "CPG", IP address "EA1, IA1, EA81, IA81", source telephone number "1001", destination telephone The number " 234-2001 " is read out and an IP packet 1333-1 (FIG. 152) is formed using the obtained information and transmitted to the alternative telephone management server (step V26).

The alternative telephone management server 1270 forms an IP packet 1333-2 (FIG. 153) using the information contained in the received IP packet 1333-1, and transmits it to the network node device 1244 (step V27). ), The network node device 1244 decapsulates the received IP packet 1333-2, forms an IP packet 1333-3 (FIG. 154), and transmits it to the media router management unit 1260 (step V28). The media router management unit 1260 receives the source telephone number "1001", the destination telephone number "234-2001", the destination IP address "EA2", and the destination UDP port number "5008" from the received IP packet 1333-3. Read and retain additional information Info-3. The media router management unit 1260 notifies the telephone 1208 that the destination telephone is being called (step V29).

Next, when the user of telephone 1216 answers the telephone call (step V31), telephone 1216 sends source telephone number " 1001 " and destination telephone number " 234-2001 " to inform the telephone 1216 of the response. Is sent to the telephone management server 1274 (steps V32, V33, V34). The telephone management server 1274 draws a source telephone number "1001" and a destination telephone number "234-2001" from the received IP packet, calculates a line number "CIC-2" from the two telephone numbers, and at least An IP packet 1334 (see FIG. 155, called an ANM packet) including the line number "CIC-2" is formed and transmitted to the telephone management server 1271 (step V35). The telephone management server 1271 draws the line number "CIC-2" and the sequence division "ANM" from the received IP packet 1334, and holds the CIC management table 1326-1 (FIG. 141) held by the telephone management server 1271 (FIG. 141). ), The record with the line number "CIC-2" is found, and the order division column of the record is rewritten as the order division "ANM".

The telephone management server 1271 then notifies the media router manager 1260 that the ANM packet has been received, that is, the telephone 1216 has responded to the telephone call (steps V36, V37, V38). 1260 sends a call signal to telephone 1208 (step V39).

<< Setting of IP Communication Record >>

The telephone management server 1274 acquires the line number "CIC-2" from the IP packets passing through the telephone management server 1274 in step V34, and from the CIC management table 1326-2 that the telephone management server 1274 has. A record with the line number "CIC-2" is found, the IP addresses "EA2", "EA1", "IA2", and "IA1" are retrieved from this record and sent to the table management server 1276 (step V42). ), The table management server 1276 sets as the second record "EA2, EA1, IA2, IA1" of the address management table 1254 in the network node device 1247 (step V43).

Similarly, the telephone management server 1271 acquires the line number "CIC-2" from the IP packet passing through the telephone management server 1271 in step V35, and from the CIC management table 1323 which the telephone management server 1271 has. A record with the line number "CIC-2" is found, the IP addresses "EA1", "EA2", "IA1", and "IA2" are retrieved from this record and sent to the table management server 1273 (step V44). ), The table management server 1273 sets as the fifth record "EA1, EA2, IA1, IA2" of the address management table 1250 in the network node device 1244 (step V45).

<< variation of connection phase >>

In addition, the media router manager 1267 can transmit a response confirmation to the telephone 1216 to the telephone 1216 (step V41), and the telephone 1208 similarly to the media router manager 1260 to confirm the response to the V V39. It can transmit (step V40). Steps V41 and V40 are options for selecting whether or not to be performed. In the above-described connection phase, the UDP port for telephone call and additional information of the telephone 1216 are transmitted in steps V22 to V29, but may be performed in steps V32 to V39 instead.

<< Communication phase >>

The telephone communication between the user of the telephone 1208 and the telephone 1216 is the same steps as described in the other embodiments, and the fifth communication IP communication record set in the connection phase ("EA1") in the address management table 1250 is performed. , EA2, IA1, IA2 "and the IP communication record (" EA2, EA1, IA2, IA1 ") of the second row in the address management table 1254 are used. Voice of telephone 1208 is digitized and carried in the payload of IP packet 1335 (FIG. 156). Here, the destination address and the UDP port number obtained in the connection phase are used. That is, the source address is the IP address "EA1" of the media router 1201 and the destination address is the IP address "EA2" of the media router 1202 connected to the destination telephone 1216, and is "5006" as the source UDP port number. "5008" is used as the destination UDP port number. The analog voice is sent from the telephone 1208 (step V50), and the voice is digitized by the media router management unit 1260 to be a voice IP packet 1335 and sent to the network node device 1244 (step V51). It is encapsulated here and becomes an IP packet 1336 (FIG. 157) to reach the network node device 1247 via the router 1263 and the router 1264 of FIG. 128 via an IP communication line (step V52), where the reverse It is encapsulated and arrives at the media router manager 1267 (step V53), and returns to analog voice to reach the telephone 1216 (step V54). The analog voice sent from the telephone 1216 is sent in the reverse direction to the above description (steps V55 to V59).

<< liberation phase >>

When the user of the telephone 1208 notifies the telephony release (step V60 in FIG. 134), the telephone management server 1271 via the media router management unit 1260, the network node device 1244, and the surrogate telephone management server 1270. (Steps V60 to V63), the telephone management server 1271 writes the end time "Ed-1" in the end time column of the record whose line number is "CIC-2" in the CIC management table 1326-1. . Next, a release IP packet 1335 (see FIG. 158, referred to as a REL packet) is formed and notified to the telephone management server 1274 (step V64), and the telephone management server 1274 manages the proxy telephone release. The telephone 1216 is notified through the server 1275 (steps V71 to V74). In addition, the telephone management server 1274 writes the end time "Ed-2" in the end time column of the record whose line number in the CIC management table 1326-2 is "CIC-2", and receives the release IP packet 1335. In order to report the result, a released IP packet 1338 (refer to FIG. 159, called an RLC packet) is formed and returned to the telephone management server 1271 (step V70).

The telephone management server 1271 informs the media router management unit 1260 via the proxy telephone management server 1270 and the network node device 1244 after step V64 (steps V65, V66, and V67). The media router management unit 1267 notifies the telephone 1216 of the release instruction (step V74), and notifies the telephone management server 1274 via the alternative telephone server (steps V75, V76, and V77).

<< Erase IP Communication Record >>

After step V64, the phone management server 1271 transmits the line number "CIC-2" written in the released IP packet 1335 to the table management server 1273 (step V78), and the internal network node device 1244 The record of the address management table 1250 corresponding to the line number "CIC-2" (the IP communication record whose contents are "EA1, EA2, IA1, IA2" in this case) is erased (step V79). After step V70, the telephone management server 1274 transmits the line number "CIC-2" written in the release completed IP packet 1338 to the table management server 1276 (step V80), and inside the network node device 1247. The record of the address management table 1254 corresponding to the line number "CIC-2" of the IP address (IP communication record whose contents are "EA2, EA1, IA2, IA1" in this case) is erased (step H81).

<< Collection of Call Information >>

When the operation management server 1277 inside the IP transmission network 1200 queries the telephone management server 1271 at a predetermined time or at an arbitrary time interval (step V200 in FIG. 162), the operation management server 1277 ends in the CIC management table 1326-1. The record for which the telephone communication is terminated is detected based on whether or not the time is written. Then, the telephone management server 1271 is notified to the telephone management server 1271 of the telephone communication record such as the source telephone number, the destination telephone number, the start time, and the end time (step V201), and the CIC management table 1326-1 of the telephone communication is terminated. Erase the record. Similarly, when the operation management server 1277 inquires the telephone management server 1274 (step V202), it detects the record for which the telephone communication is terminated by clinging to whether or not the end time is written in the CIC management table 1326-2. do. Then, the telephone management server 1274 is notified of the telephone communication records such as the source telephone number, the destination telephone number, the start time, and the end time (step V203), and the CIC management table 1326-2 of the telephone communication is terminated. Erase the record. With such a configuration, it is possible to collect telephone communication records via the telephone management server, that is, the source telephone number, the destination telephone number, the start time, the end time, and the like, for use in charging the telephone communication. The call information may be collected or not.

<< Outgoing line management and incoming line management >>

In the connection phase, the telephone management server 1271, at the time of formation of the IAM packet 1327 (step V9) (step V9), transmits an address " EA1 " Increases the number of lines in use corresponding to "1". Similarly, the telephone management server 1274 increases the number of active lines corresponding to the address " EA2 " of the destination media router in the incoming line management table 1326-6 in Fig. 161 by " 1 ".

In the release phase, the telephone management server 1271, at the time of forming the REL packet 1357 of FIG. 158 (step V64), shows the address " EA1 " of the transmitting media router of the outgoing line management table 1326-5 of FIG. Decreases the number of active lines corresponding to " 1 ". Similarly, the telephone management server 1274 corresponds to the address " EA2 " of the destination media router in the incoming line management table 1326-6 in FIG. 161 when the RLC packet 1338 in FIG. 159 is formed (step V70). Decreases the number of lines in use by "1". The outgoing line management and the incoming line management can be selected.

<< Another example of connection phase >>

In the connection phase (steps V0 to V45), a response confirmation step (steps V90 to V96) may be added, which will be described with reference to FIG. 163. When the media router management unit 1260 receives the response notification (step V38), the media router manager 1260 may form and reply to an IP packet indicating a response confirmation notification, and the response IP packet for response confirmation is the network node device 1244 and the proxy telephone management server. 1270, the telephone management server 1271, the telephone management server 1274, the telephone agent server 1275, and the network node device 1247 are sent to the media router management unit 1267 (steps V90 to V96). In this way, the reliability of communication can also be improved.

<< Another example of the liberation phase >>

The next step is possible instead of the release phases (steps V60 to V77), which will be described with reference to FIG. 163.

When the user of the telephone 1208 notifies the telephone communication release (step V100 in FIG. 168), the media router management unit 1260, the network node device 1244, the surrogate telephone management server 1270, the telephone management server 1271, The telephone 1216 is notified via the telephone management server 1274, the alternative telephone management server 1275, the network node device 1247, and the media router manager 1267 (steps V100 to V108). When the media router management unit 1267 receives the release notification (step V107), the media node management unit 1247, the surrogate telephone management server 1275, and the telephone management server 1274 are provided in the reverse direction to the above description to inform the release acceptance. ), The media router management unit 1260 is informed via the telephone management server 1271, the proxy telephone management server 1270, and the network node device 1244 (steps V111 to V118). Subsequently, the release completion notification is routed as described above, that is, the network node device 1247, the surrogate telephone management server 1275, the telephone management server 1274, the telephone management server 1271, and the surrogate telephone management server 1270. The media router management unit 1260 is informed via the network node device 1244 (steps V121 to V127). In addition, erasing the record used for voice communication in the address management table 1250 in the network node device 1244 and the address management table 1254 in the network node device 1247 is performed in steps V80 and V81, or in step V78 and Same as V79. Reliability can be increased by two steps: receipt of liberation and completion of liberation.

<< Adoption of TCP Technology >>

In the connection phase and the release phase, communication between the phone management server 1271 and the phone management server 1274, that is, instead of performing steps V9, V16, V25, V35, V64, and V70 shown in FIG. 134 by UDP communication. And TCP communication, which will be described below with reference to FIGS. 164 to 169.

164 shows an example of performing step V9 by TCP communication, and transmits a TCP packet 1390-1 including a SYN designation for establishing a TCP connection from the telephone management server 1271 to the telephone management server 1274. The telephone management server 1274 replies the TCP packet 1391-1 containing the ACK indication of the communication start receipt, and the same content as the IP packet 1327 from the telephone management server 1271 to the telephone management server 1274. The TCP packet 1332-1 including the (call setting IAM notification) is transmitted (step V9t). Next, a TCP packet 1393-1 containing a FIN designation for terminating a TCP connection is transmitted from the telephone management server 1271 to the telephone management server 1274, and the telephone management server 1271 is received from the telephone management server 1274. ) Returns a TCP packet 1394-1 for confirmation of termination.

165 shows an example of performing step V16 by TCP communication, transmits a TCP packet 1390-2 including the SYN designation for establishing a TCP connection from the telephone management server 1274 to the telephone management server 1271. The telephone management server 1271 replies the TCP packet 1371-2 including the ACK indication of the communication start receipt, and the same contents as the IP packet 1331 from the telephone management server 1274 to the telephone management server 1271 ( The TCP packet 1932-2 including the call setup acceptance ACM notification) is transmitted (step V16t). Next, a TCP packet 1393-2 including a FIN designation for terminating a TCP connection is transmitted from the telephone management server 1274 to the telephone management server 1731, and the telephone management server 1274 is transmitted from the telephone management server 1773. ) Returns the TCP packet 1394-2 for the termination confirmation.

166 shows an example of performing step V25 by TCP communication, transmits a TCP packet 1390-3 including the SYN designation for establishing a TCP connection from the telephone management server 1271 to the telephone management server 1274, The telephone management server 1274 replies the TCP packet 1391-3 including the ACK indication of the communication start receipt, and the same contents as the IP packet 1333 from the telephone management server 1271 to the telephone management server 1274 ( The TCP packet 1332-3 including the call passing CPG notification) is transmitted (step V25t). Next, the telephone management server 1271 transmits a TCP packet 1393-3 including the FIN designation for terminating the TCP connection to the telephone management server 1274, and the telephone management server 1271 from the telephone management server 1274. ) Returns the TCP packet 1394-3 for the termination confirmation.

167 shows an example in which step V35 is carried out by TCP communication, and the TCP packet 1392 includes the same contents (call-through ANM notification) as the IP packet 1334 from the telephone management server 1271 to the telephone management server 1274. -4) is transmitted (step V35t), and can be implemented in the same manner as the above-described other method. 168 shows an example in which step V64 is performed by TCP communication, and the TCP packet including the same contents (release REL notification) as the IP packet 1335 from the telephone management server 1271 to the telephone management server 1274. 1392-5) is transmitted (step V64t), and can be implemented in the same manner as the above-described other methods.

FIG. 169 shows an example in which step V70 is carried out by TCP communication, and includes a TCP packet 1332 including the same contents (release completion RLC notification) as the IP packet 1338 from the telephone management server 1274 to the telephone management server 1271. -6) is transmitted (step V70t), and can be carried out in the same manner as the above-described other method.

<Separation of control line and call line>

Next, it will be described that in an open area telephone communication, an IP communication line used for terminal-to-terminal connection control and a communication line used for voice communication can be separated.

IP packets 1322, 1327, 1328, 1331, 1332-2, 1333, 1333-1, 1334, 1337, and 1338, which are used for terminal-to-terminal access control, are alternate phone management server 1270, telephone management server 1271, It is transmitted in the range 1289 (FIG. 170) of any one of the IP communication lines connecting the telephone management server 1274 and the alternative telephone management server 1275. On the other hand, the IP packets 1335 and 1336 used for voice communication are in the range 1293 of the IP communication line connecting the network node device 1244, the router 1291, the router 1292, and the network node device 1247. 170). The IP communication line used for the terminal-to-terminal connection control corresponds to the common line signal network line of the switched communication network, and the communication line used for the voice communication can correspond to the voice communication line of the switched communication network.

In this way, the network node device 1244 transmits the IP packet for the terminal-to-terminal communication connection transmitted from the media router 1201 to the router 1263, and separately transmits the IP packet for voice communication to the router 1231. The flow of IP packets in the reverse direction is collectively transmitted to the media router 1201 by integrating the IP packets for the terminal-to-terminal communication connection and the IP packets for the voice communication.

<< Phone DNS Server with Tree Structure of Phone Numbers >>

The tree structure shown in FIG. 171 is a tree structure of telephone numbers managed by the telephone number server 1140 of the company B, and domains 1251 to 1254 are related in a tree structure form at the same level under the root 1250, Domain 1251 has the telephone number "1 ×××" (1000 phone numbers), domain 1252 has the telephone number “2 ×××”, domain 1253 has the telephone number “3 ×××”, domain 1254 has the other Each IP address associated with a telephone number is managed. The tree structure shown in FIG. 172 is a tree structure of telephone numbers managed by the telephone number server 1142 of the company A, and domains 1251-2, 1251-3, and 1254 are related to the same level of tree structure under the root 1251. Domain 1251-2 manages company A's telephone number “1 ×××”, domain 1251-3 manages company A's domain “#”, and domain 1251-4 manages company A's extension telephone number “1”. Domain 1251-5 manages the extension telephone number "2xx" of company A, and domain 1251-6 manages the IP address regarding the extension telephone number "3xx" of company A, respectively.

Here, the domain "#" is the private secret of Company A and private to other companies. That is, in response to a question from a telephone number server belonging to company B or company C other than the company A, the telephone number server 1142 replies the information about the domains 1151-4 to 1151-6 in the range of the domain "#". It is not supposed to be done. Domain 1254 manages IP addresses related to other telephone numbers.

The tree structure shown in FIG. 173 is a tree structure of phone numbers managed by the telephone number server 1137 of the company A, and domains 1251 to 1254 are related in a tree structure at the same level under the root 1250-1, and the domain 1251 Is the phone number belonging to Company A, domain 1252 is the company B's phone number "2 ×××", domain 1253 is the company C's phone number "3 ×××", and domain 1254 is the IP for other phone numbers. Manage each address. Domain 1251-2 manages company A's telephone number "1 ×××", domain 1251-3 manages company A's domain “#”, and domain 1251-4 manages company A's extension telephone number “1 ×××”. "Domain 1251-5 manages the extension telephone number" 2xx "of company A, and domain 1251-6 manages the IP address regarding the extension telephone number" 3xx "of company A, respectively.

Here, the domain "#" is the private secret value of the company A described above. The tree structure shown in Fig. 174 is a tree structure of telephone numbers managed by the telephone number server 1139 of the company X, and domains 1254-2 and 1254 are related to the tree structure type at the same level under the root 1250-2. Domain 1254-2 manages telephone numbers belonging to company X, and domain 1254 manages IP addresses relating to other telephone numbers, respectively.

Table 1255-1 in FIG. 175 shows how the media router management unit 1260 converts the telephone number that the telephones 1208 to 1211 connected to the media router 1201, as the call counterpart, into a domain name. The first line telephone number "1xxx" of the table 1255-1, for example, the telephone number "1001" is represented by the telephone number domain name "1.a.", and the second line of the table 1255-1. Means that the telephone number "2xxx" is represented by the telephone number domain name "b.", And telephone numbers other than the seventh line of the table 1255-1 are represented by the telephone number domain name "0.", The other lines are the same. The telephone number server 1137 answers the IP address " EA1 " in response to, for example, the telephone number domain name " 1.a. " according to the table 1255-2 of FIG. 176, and the telephone number domain name " b " . "Is returned, and IP address" EA5 "is returned, and telephone number domain name" 0. "is asked, and IP address" EA81 "is returned.

Table 1256-1 in FIG. 177 shows how the media router management unit 1264 converts the telephone number, which the telephones 1228 to 1231 connected to the media router 1203 make as a call counterpart, to a domain name. Table 1256 The first line telephone number " 1 ××× " of -1 is expressed by the telephone number domain name " 1.a. ", and the second line telephone number " 1 ×× "# .a. ", which means that a phone number other than the fifth line of Table 1256-1 is represented by the telephone number domain name" 0. ", and the other lines are also the same. The telephone number server 1142 answers the IP address " EA1 " in response to, for example, the telephone number domain name " 1.a. " according to Table 1256-2 in FIG. 178, and the telephone number domain name " 1. # &Quot; "a.", the IP address "EA1" is returned, and telephone number domain name "0." is asked, and the IP address "EA81" is returned.

Table 1257-1 in FIG. 179 shows a method in which the media router management unit 1266 converts the telephone number, which the telephones 1220 to 1223 connected to the media router 1205, as a call counterpart, into a domain name. Table 1257-1 Line 1 telephone number "1 ×××" of the telephone line is represented by the telephone number domain name "a.", And line 2 telephone number "2 ×××" of the table 1257-1 is represented by the telephone number domain name "b." In addition, it is represented by telephone number domain name "0." other than the 4th line of Table 1 256-1, and the other line is also the same. The telephone number server 1140 receives the telephone number domain name "a.", For example, answers the IP address "EA1" according to Table 1257-2 of FIG. 180, and asks the telephone number domain name "b." The IP address "EA5" is returned, and the telephone number domain name "0." is asked and the IP address "EA81" is returned.

The telephone number servers 1137 to 1142 call other telephone number servers by using the known recursive calling function of the domain name server DNS to obtain IP addresses directly managed by the other telephone number servers.

The above is summarized as follows. That is, Media Router 1 and Media Router 2 are connected via an IP transport network, Phone 1 is connected to Media Router 1, Phone 2 is connected to Media Router 2, and Phone 1 and Phone 2 are inside Media Router 1. The telephone number server of can be used for telephone communication without using the telephone number server in the IP transmission network. In addition, a plurality of telephones may be connected to the media router 1 or the media router 2. In addition, the IP transport network includes a unique telephone number server, and the telephones 1 and 2 can access the telephone number server in the IP transport network and use the telephone number server inside the media router 1 to communicate with the telephone 2.

The IP transport network includes two or more network node devices, and the media router is connected to any one of the network node devices via a logical IP communication line, and an internal IP address is provided at a network node device end of the logical IP communication line. Each media router is assigned an external IP address, has a telephone number server inside, and the media router is connected to one or more telephones via a communication line. As the record of the address management table inside the network node apparatus, the external IP address and the communication record are set in advance, and the connection phase of the telephony communication is call setup (IAM), call setup acceptance (ACM), call passing (CPG), and response. It consists of a series of steps which consist of (ANM), and the release phase of telephone communication consists of a series of steps which consist of release (REL) and release completion (RLC). In addition, a response acknowledgment (ACK) may be performed after the response (ANM) to release the reception between the release REL and the release completion RLC.

In summary, an IAM packet, an ACM packet, a CPG packet, an ANM packet, an REL packet, and an RLC packet are transmitted and received between the calling telephone management server and the called telephone management server. In localized telephony that limits the parties, the telephone number server inside the media router is used. In localized telephony that does not define the parties, the telephone number server inside the IP router is used by the telephone number server inside the media router. do. In local telephone communication, an IP communication line used for terminal-to-terminal connection control and a communication line used for voice communication can be separated. The telephone management server can record the source telephone number, the destination telephone number, the telephony start time, and the end time with the CIC management table. The operation management server queries the telephone management server to obtain the source telephone number, the destination telephone number, the telephony start time, and the end time, which can be used for billing.

11. Eleventh embodiment for carrying out telephone transmission from public telephone network:

<< Preparation >>

A description will be given with reference to FIG. The telephone 520 has a telephone number "03-5414-8510" and is connected to the exchange 513 via the telephone line 517. The communication line 524-1 connects the switch 514-1 and the gateway 521-1, and the interface is an NNI including a common line signal line and a call line, and is defined by a common line signaling method on a common line signal line. The signal unit is transmitted. The gateway 521-1 is given a GW logical name (gateway logic name) "GW5211" which is open to the public and a signal station code "# 1234" which can be identified from the public switched telephone network 515 side. It is. The subscriber switching centers 513 and 511 have a set of the GW logical name "GW5211" and the signal station code "# 1234" in advance. The communication line 524-2 connects the switch 514-2 and the gateway 521-2, and the interface is UNI. The telephone number "03-1111-2222" is attached to the end of the gateway 521-2 side of the communication line.

<< Preparation of NNI Line Incoming Transmission >>

The owner of the telephone 520 disconnects the telephone 520 from the telephone line 517 and connects as the telephone 530 to the communication line 528 connecting to the media router 527. The telephone number of the telephone 530 is "03-5414-8510". The user 532 of the telephone 520 connects the telephone 520 to the acceptance 533 of the public switched telephone network to the IP transmission network 522 at the position of the telephone 530, that is, the gateway "GW5211". Notified of the conversion (step H01 in FIG. 182), the reception 533 informs the change contents, that is, the telephone number " 03-5414-8510 " and the GW logical name " GW5211 " 513). (Step H02). The exchange 513 converts the GW logical name "GW5211" into the signal station code "# 1234" by using the information held therein, and transmits the telephone number "03-5414-8510" and the transmission line gateway to the transmission processing unit 516. The set of signal station code "# 1234" of (521-1) is stored (step H03).

<< NNI line forwarding >>

When a call is sent from the telephone 510 having the telephone number " 047-325-3897 " to the destination telephone number " 03-5414-8510 " (step H05), the switch 511 accepts the call origination (step H06). . Next, the telephone line 520 is called from the switch 511 via the communication line 512 to the switch 513 (step H08). The exchange 513 finds the telephone number "03-5414-8510" previously stored in the transmission processing unit 516 and the signal station code "# 1234" of the transmission line gateway 521-1 (step H09). 511) notifies the acquired signal station code "# 1234" (step H10). The exchange 511 uses the signal station code "# 1234 " as the address of the received gateway 521-1 as a destination, and the destination telephone number " 03-5414-8510 " When a signal unit including a signal is formed and transmitted, the signal unit passes through the exchange 514-1 (step H11) and reaches the gateway 521-1 through the communication line 524-1 (step H12). . Thereafter, the router 525-1 passes through the telephone management server 525 (step H15), the connection control line 524-5, the router 525-2, the connection control line 524-4, and the network. The media router 527 is reached via the node apparatus 523-2 (step H16) and via the communication line 526 (step H17). When the media router 527 transmits the telephone call reception notification for the dial-up request in the opposite direction, the telephone call reception notification passes through the network node device 523-2 (step H21), and the telephone management server 525 ) Is reached (step H22), and the gateway 521-1 is reached (step H23). The gateway 521-1 notifies the switch 511 of the telephone call origination reception via the switch 514-1 (step H25) (step H26).

Next, when the media router 527 calls the telephone 530 with the telephone number "03-5414-8510" past the communication line 528 (step H28), the notification that the incoming call is busy is reversed from the above, i.e. The media router 527, the network node device 523-2, the connection control line 524-4, the telephone management server 525, the gateway 521-1, the switch 514-1, and the switch 511 The telephone 510 which made the call originating is notified (step H30-H37). When the user of the telephone 530 picks up the handset (off-hook), the telephone 530 notifies the media router 527 of the response notification (step H40). The following is the same as described above, and the media router 527, A telephone that has made a call through the network node device 523-2, the connection control line 524-4, the telephone management server 525, the gateway 521-1, the exchange 514-1, and the exchange 511 ( 510 is notified (steps H41 to H47).

The connection control data for the telephone call connection transmitted and received as the steps H11, H12, and H15 is called an IAM message, and the connection control data between the steps H23, H25, and H26 is called an ACM message, and the connection between the steps H33, H35, and H36 is performed. The control data is called a CPG message, and the connection control data between steps H43, H45, and H46 is called an ANM message. The message IAM, ACM, CPG, or ANM does not pass through the network node device 523-1 in the telephone call access phase. That is, the message is directly transmitted and received between the gateway 521-1 and the telephone management server 525.

By this arrangement, the communication connection sequence between the telephone 510 and the telephone 530 is completed, and the telephone call by the voice between the telephone 510 and the telephone 530 is possible. The voice transmitted from the telephone 510 arrives at the gateway 521-1 through the switch 511, the switch 514-1, and the communication line 524-1, and digitizes at the gateway 521-1. Becomes the voice which has been made, and the network node apparatus 523-1, the communication line 524-3, the router 525-2, the communication line 524-6 for the voice communication, the network node apparatus 523-2, the media router 527, the digitized voice is analogized at the media router 527 to reach the phone 530. In addition, the voice transmitted from the telephone 530 is transmitted via the communication path opposite to the above to reach the telephone 510.

At the end of the telephone call, call release from the telephone 510 is sent to the switch 511 (step H50), passes through the switch 514-1 (step H51), and is notified to the gateway 521-1 ( Step H 53), the gateway 521-1 sends a call release completion notification to the exchange 511 (steps H54, H55).

Next, the gateway 521-1 sends the release of the telephone call obtained in the above procedure to the telephone 530 via the IP transmission network 522 (steps H61 to H64), and the call release completion notification is sent to the media router 527. Is conveyed to the gateway 521-1 (steps H65 to H67). It is described by another embodiment that the call can be released in the reverse direction, from the telephone 530 towards the public switched telephone network 515. The connection control data for the telephone call release of the steps H51, H53, and H61 is called an REL message, and the connection control data of the steps H67, H54, and H55 are called an RLC message.

Further, without performing the steps H01 to H03, the owner 532 of the telephone 520 enters the position of the telephone 530, that is, the gateway "GW5211" from the telephone 520 having the telephone number "03-5414-8510". After notifying the switch 513 via the communication line 517 of the advance notice of connection conversion to the IP transmission network 522d, the phone 520 can be connected to the location of the phone 530 (Fig. Step 01X of step 182), the switch 513 then converts the GW logical name "GW5211" into the signal station code "# 1234" using the information held above, and transmits the telephone number "03-" to the transmission processing unit 516. A method of retaining a set of 5414-8510 "and the signal station code" # 1234 "of the transmission line gateway 521-1 may be employed (step H03X).

By the above, the description of the incoming call transmission via the NNI line is finished, and the incoming call transmission according to UNI will be described next.

<< Preparation of UNI Line Incoming Transmission >>

This will be described with reference to FIGS. 181 and 183. The owner of the telephone 520 disconnects the telephone 520 from the telephone line 517 and connects to the communication line 528 as the telephone 530. The telephone number of the telephone 530 is "03-5414-8510". Next, the user 532 of the telephone 520 notifies the reception 533 that the telephone 520 is connected and switched on (step H01), and the reception 533 transmits the change contents via the communication line 534. 513 is notified (step H02). The exchange 513 has the telephone number " 03-1111 given to the transmission processing unit 516 at the terminal end of the transmission line gateway 521-2 side of the telephone number " 03-5414-8510 " and the communication line 524-2. A set of -2222 " is stored (step H03-2).

<< UNI line forwarding >>

In this case, the switch 514-2 is used instead of the switch 514-1, and the gateway 521-2 is used instead of the gateway 521-1. For this reason, the terminal-to-terminal communication connection control procedure between the switch 514-2 and the gateway 521-2 is characterized by new steps H12-2 and H13-2, which will be described below.

If the call is sent from the telephone 510 with the telephone number "047-325-3897" to the destination telephone number "03-5414-8510" (step H05-2), the exchange 511 accepts the call origination (step H06). -2). Next, the telephone 520 is telephoned to the switch 513 (step H08-2) via the communication line 512 from the switch 511. The switch 513 has the telephone number " 03-5414-8510 " stored in advance in the transmission processing section 516 and the telephone number " 03 given to the end of the input line 524-2 of the transmission line gateway 521-2. -1111-2222 "is found (step H09-2), and the exchange 511 is notified of the acquired telephone number" 03-1111-2222 "(step H10-2). The exchange 511 uses the telephone number " 03-1111-2222 " of the input line of the received gateway 521-2 as a destination, and a signal including the destination telephone number " 03-5414-8510 " When the unit is formed and transmitted, the signal unit arrives at the exchange 514-2 (step H11-2). If a dial-up request (SETUP) included in the signal unit is sent to the gateway 521-2 through the communication line 524-2 (step H12-2), the gateway 521-2 returns the step H12-2. The switch 514-2 is notified that the telephone call connection request has been received (step H13-2). Further, after passing through the network node device 523-1 (step H14-2), passing through the router 525-2, and via the telephone management server 525 (H15-2), the router 525-2, It passes through the connection control line 524-4, the network node apparatus 523-2 (step H16-2), and reaches the media router 527 through the communication line 526 (step H17-2).

When the media router 527 sends the telephone call reception notification for the dial-up request in the opposite direction, the telephone call reception notification passes through the network node device 523-2 (step H21-2), and the telephone management server ( Passing 525 (step H22-2), passing through network node device 523-1 (step H23-2), and reaching gateway 521-2 (step H24-2). The gateway 521-2 notifies the switch 511 of the telephone call origination acceptance via the switch 514-2 (step H25-2) (step H26-2).

Next, when the media router 527 calls the telephone 530 with the telephone number "03-5414-8510" past the communication line 528 (step H28-2), the notification that the incoming call is in the reverse direction to the above. That is, the media router 527 (step H30-2), the network node device 523-2 (step H31-2), the telephone management server 525 (step H32-2), and the network node device 523-1. (Step H33-2), Gateway 521-2 (Step H34-2), Switch 514-2 (Step H35-2), Switch 511 (Step H36-2). 510 is notified (step H37-2).

When the user of the telephone 530 picks up the handset (off-hook), the telephone 530 notifies the media router 527 of the response notification (step H40-2), and the following is the same as described above and the media router 527. ), The network node device 523-2, the telephone management server 525, the network node device 523-1, the gateway 521-2, the switch 514-2, the switch 511, and the call origination. One telephone 510 is notified (steps H41-2 to H47-2). In the telephone call connection phase, a message is transmitted and received via the network node device 523-1 for the connection phase between the gateway 521-2 and the telephone management server 525. FIG.

By the above, the communication connection order between the telephone 510 and the telephone 530 is completed, and the telephone call by the voice between the telephone 510 and the telephone 530 is enabled.

<< Call Phase and Liberation Phase >>

The call phase and release phase are the same as the case of the NNI line incoming transmission, except that the switch 514-2 is used instead of the switch 514-1, and the gateway 521-2 is used instead of the gateway 521-1. ) Are used (steps H50-2 to H53-2, H54-2 to H55-2, H60-2 to H63-2, and H65-2 to H68-2).

<< Another embodiment of incoming transmission via UNI >>

This will be described with reference to FIGS. 181 and 184. The owner of the telephone 520 disconnects the telephone 520 from the telephone line 517 and connects as the telephone 530 to the communication line 528 connecting to the media router 527 as the UNI line incoming transmission of the above embodiment. Is the same as the preparation.

<< UNI line forwarding >>

In this UNI line incoming transmission, the switch 511 and the switch 514-2 transmit and receive a connection control message via the switch 513, and will be described below.

When the call is sent from the telephone 510 having the telephone number "047-325-3897" to the destination telephone number "03-5414-8510" (step H05-3), the exchange 511 receives the call and receives it (step H06-). 3) The telephone 520 is telephoned to the switch 513 via the communication line 512 from the switch 511 (step H08-3). The switch 513 has the telephone number " 03-5414-8510 " stored in advance in the transmission processing section 516 and the telephone number " 03 given to the end of the input line 524-2 of the transmission line gateway 521-2. -1111-2222 " (step H09-3), and then the telephone number " 03-1111-2222 " of the input line of the gateway 521-2 is set as the destination, and the destination telephone number " 03 " When a signal unit including -5414-8510 "is formed and transmitted, the signal unit arrives at the exchange 514-2 (step H11-3). If a dial-up request (SETUP) included in the signal unit is sent to the gateway 521-2 through the communication line 524-2 (step H12-3), the gateway 521-2 returns the step H12-3. The switch 514-2 is notified that the telephone call connection request has been received (step H13-3). Furthermore, after passing through the network node device 523-1 (step H14-3), passing through the router 525-2, via the telephone management server 525 (step H15-3), the router 525-2 again. After passing through the connection control line 524-4 and the network node device 523-2 (step H16-3), the communication path 526 is reached through the media router 527 (step H17-3).

When the media router 527 sends the telephone call reception notification for the dial-up request in the opposite direction, the telephone call reception notification passes through the network node device 523-2 (step H21-3), and the telephone management server ( Passing 525 (step H22-3), passing through network node device 523-1 (step H23-3), and reaching gateway 521-2 (step H24-3). The gateway 521-2 notifies the switch 511 of the telephone call origination reception via the switch 514-2 (step H25-3) and via the switch 513 (step H26-3). (Step H27-3).

Next, when the media router 527 calls the telephone 530 with the telephone number "03-5414-8510" past the communication line 528 (step H28-3), the notification that the incoming call is in the reverse direction to the above. That is, the media router 527 (step H30-3), the network node device 523-2 (step H31-3), the telephone management server 525 (step H32-3), and the network node device 523-1. (Step H33-3), through the gateway 521-2 (step H34-3), the exchange 514-2 (step H35-3), the exchange 513 (step H36-3), and the exchange 511 (Step H37-3), the telephone 510 which made the call transmission is notified (step H38-3). When the user of the telephone 530 picks up the handset (off-hook), the telephone 530 notifies the media router 527 of the response notification (step H40-3), and the following is the same as described above and the media router 527. ), Network node device 523-2, telephone management server 525, network node device 523-1, gateway 521-2, exchange 514-2, exchange 513, exchange 511 The call 510 is notified after the call (steps H41-3 to H48-3).

By the above, the communication connection sequence between the telephone 510 and the telephone 530 is completed.

<< Call Phase and Liberation Phase >>

The call phase and the release phase are the same as those of the UNI circuit incoming transmission case, except that the switch 511 and the switch 514-2 transmit and receive a connection control message via the switch 513.

By the principle described above, the analog telephone 510 connected to the public switched telephone network 515 has a media router 527 having the telephone number "03-5414-8510" used by the public switched telephone network via the IP transmission network 522. Communication between the analog telephone 530 connected to the terminal) is possible. In addition, the media router can be installed inside the LAN as described in another embodiment. For this reason, a telephone having a telephone number " 03-5414-8510 " used in a public switched telephone network is connected to a media router inside a LAN, and an IP transmission network (from an analog telephone 510 connected to the public switched telephone network 515) is connected. Via 522, communication between terminals is possible by connecting to an analog telephone in the LAN having the telephone number " 03-5414-8510 ".

In summary, the relay switch 514-1 and the IP transport network 522 of the public switched telephone network 515 are transmitted by a method of transmitting a call call connection request to a phone connected to a public switched telephone network to a phone connected to an IP transport network. Gateway 521-1 is connected to the NNI interface communication line 524-1, and the telephone 520 having the telephone number " TN-1 " connected to the subscriber switch 513 is connected to the IP transmission network 522. It connects to the connected media router 527 as telephone number "TN-1", and calls telephone number "TN-1" from telephone 510 which is telephone number "TN-2" connected to subscriber exchange 511. When a connection request is made, the connection request arrives at the subscriber switch 513, and the connection request is transmitted by the relay switch 514-1 and the NNI interface communication line 524-1 by the incoming transmission function of the subscriber switch 513. Phone via gateway 521-1, IP transport network 522, and media router 527 It is to arrive at 530.

The subscriber switch 514-2 of the public switched telephone network 515 and the gateway 521-2 of the IP transport network 522 are connected by a UNI interface communication line 524-2, and the public switched telephone network 515 is connected. Telephone 520 having telephone number " TN-1 " connected to subscriber exchange 513 of " " is connected to media router 527 connected to the IP transport network as telephone number " TN-1 " When a telephone call connection request is made to the telephone number "TN-1" from the telephone 510 having the telephone number "TN-2" connected to the telephone number, the connection request reaches the subscriber switch 513, By the incoming transmission function, the connection request is transmitted through the subscriber switch 514-2, the UNI interface communication line 524-2, the gateway 521-2, the IP transmission network 522, and the media router 527. 530.

12. Twelfth embodiment performing telephone transmission from public telephone network:

<< Preparation >>

In FIG. 185, reference numeral 540 denotes an IP transmission network, reference numerals 541 to 545 denote network node devices, reference numerals 546-1 to 546-5 denote relay devices (routers), and reference numerals 550 and 554 denote gateways including line information. ", Reference numerals 551, 552, and 553 are gateways. These network node devices, relay devices, and gateways are each connected directly or indirectly through the relay device via a communication line having an IP packet transmission function. Reference numerals 555 to 556 denote a public switched telephone network (PSTN), reference numerals 557 to 566, switchboards, reference numerals 570 to 573, telephones, reference numerals 597 and 598 telephones, and reference numerals 576 to 578 denote network network interfaces (NNI) Communication lines, reference numerals 580 to 581 denote communication lines having a user network interface (UNI), and reference numeral 583 denote communication lines having an IP packet transmission function. Reference numerals 584 and 585 denote IP transmission network input circuit tables, and reference numerals 586 to 590 denote IP transmission network output circuit tables. Reference numeral 591 denotes a media router. Reference numerals 593 to 594 denote telephone number servers, and are connected to router 546-1 or router 546-3 via a communication line. The gateways 550 and 554 connecting to the NNI communication line are separately provided with signal station codes for identification from the public switched telephone network side and IP addresses for identification from the IP transmission network 540, respectively.

The communication provider identification code "00XY" is assigned to the gateway 550 including the line information, and the service provider identification code "00UV" is assigned to the gateway 554 including the line information. Signaling station code "# 2222" is given to gateway 551, and telephone number "03-4444-4000" is given to the entrance of communication line 580 side of gateway 552. The telephone number servers 593 to 594 have a function of returning the IP address of the gateway having the telephone number or the IP address of the media router MR having the telephone number when the telephone number is presented. Output line tables 586 to 590 include IP address information corresponding to all telephone numbers owned by the gateway or media router. The telephone number of the telephone 570 is "03-1111-2222", the telephone number of the telephone 571 is "06-3333-4444", and the telephone number of the telephone 572 is "092-555-6666". , The telephone number of the telephone 597 is "07-3333-4444", and the telephone number of the telephone 598 is "093-555-6666", respectively, inside the public switched telephone network 555 or 556 across the communication line. The telephone 573 is telephone number "045-777-8888" and is connected to the media router 591 via a communication line.

Fig. 186 shows the contents (example) of IP transmission network input line table 584, and in the case of the first row record, the telephone whose range of destination telephone number is from "06-0000-0000" to "06-9999-9999". The classification of the gateway for connecting the communication line to the network is NNI, indicating that the signal station code of the gateway is "# 2222". In this case, the gateway is 551. The same applies to the fifth row record. In the second line, the division of the gateway for connecting the communication line to the telephone whose range of the destination telephone number is from "092-0000-0000" to "092-999-9999" is UNI. The telephone number is in the range of "03-4444-4000" to "03-4444-4099". In this case, the gateway is 552. The same applies to the third row record and the fourth row record. The content of the IP network input circuit table 585 includes the same contents as the IP network input circuit table 584.

Fig. 187 shows the contents (example) of IP transmission network output line table 586, and in the case of the first row record, the telephone whose range of destination telephone number is from "06-0000-0000" to "06-9999-9999". A gateway (GW) or a media router (MR) for connecting a communication line to the IP network is connected to the IP transmission network, and the IP address of the GW or MR indicates "10.240.240.1" to "10.240.240.255". The same is true of the row record. The contents of the IP transport network output circuit table 587 to 590 include information similar to that of the IP transport network output circuit table 586.

<< Communication connection control between telephones -1 >>

185 shows an example of telephone connection from the source telephone 570 with the telephone number "03-1111-2222" to the destination telephone 571 with the telephone number "06-3333-4444". 590-1 in FIG. 188 denotes a dial-up connection inside the public switched telephone network 555, 590-2 denotes a dial-up connection inside the IP transmission network 540, and 590-3 denotes a dial-up connection inside the public switched telephone network 556. Represents a dial-up connection respectively. This will be described with reference to FIGS. 188 and 189.

When the telephone 570 dials " 00XY-06-3333-4444 " (step J01 in Fig. 188), the switch 557 confirms the call (step J02), and the switch 557 dials the dialed information. The switch 558 connected to the gateway 550 containing the line information to which "00XY" has been assigned using the carrier identification code "00XY" contained in the " 00XY " 03-1111-2222 "and" 00XY-06-3333-4444 "are transmitted to the exchange 558 (step J03). The exchange 558 then transmits the source telephone number "03-1111-2222" and the destination telephone number "06-3333-4444" to the gateway 550 including the line information (step J04), and sends the line information. The containing gateway 550 refers to the IP transmission network input line table 584 inside the gateway 550 containing the line information as a parameter of the telephone number of the destination telephone, that is, the destination telephone number is "06-3333-4444". As the access information to the gateway for connecting the communication line to the mobile telephone, the gateway knows that the gateway has an NNI interface, and the signal station code of the gateway as the signal station is "# 2222", and returns to the exchange 558 (step J05). ). Next, the exchange 558 finds an exchange that connects to the gateway having the signal station code "# 2222", and in this case, finds that it is the exchange 559, and finds the signal station code as access information to the gateway obtained by the above procedure. # 2222 ", information including the source telephone number" 03-1111-2222 "and the destination telephone number" 06-3333-4444 "is transmitted to the exchange 559 (step J06).

The exchange 559 transmits the source telephone number "03-1111-2222" and the destination telephone number "06-3333-4444" to the gateway 551 having the signal station code "# 2222" past the NNI communication line 577. (Step J07). The gateway 551 forms an IP packet including the source telephone number "03-1111-2222" and the destination telephone number "06-3333-4444" obtained by the above procedure. The source IP address of the IP packet is an IP address assigned to the gateway 551 (known by the gateway 551 itself), and the destination IP address is a communication counterpart for connecting a communication line, in this case, the gateway 554. IP address "10.240.240.1", which corresponds to the destination telephone number "06-3333-4444" as a parameter from the IP transmission network output line table 586 (FIG. 187) inside the gateway 551. This is an example of using "10.240.240.1" which is one of the IP addresses. Instead of the above-described process of the gateway 551 discovering the IP address of the gateway 554, connecting to the telephone having the destination telephone number "06-3333-4444" from the gateway 551 to the telephone number server 593. A " query IP packet " for querying the IP address of the gateway can be sent, and a response can be obtained from the telephone number server 593 (optional).

Among the functions of the above-mentioned exchange, "step J04" and "step J05" can use the messages of the common circuit signal system / transaction function unit of the telephone exchange network.

The IP packet formed as described above is sent from the gateway 551 to pass through the router 546-1 and the telephone management server 549-1 (step J08), the router 546-1, and the router 546-5. , After passing through the telephone management server 549-5 (step J09), after passing through the router 546-5, the gateway 554 (step J10), and passing through the NNI communication line 578 to reach the exchange 562 ( Step J11). The IP packet includes a source telephone number "03-1111-2222" and a destination telephone number "06-3333-4444".

Subsequently, a call setup request including the source telephone number "03-1111-2222" and the destination telephone number "06-3333-4444" is sent to the exchange 561 (step J12), and the call setup request is received. One switch 561 returns a confirmation notification of the call setting request to the switch 557 (steps J14 to J20). Next, the exchange 561 calls the telephone 571 (step J13), and returns to the exchange 561 that the telephone is being called (step J22), the exchange 561 determines that the destination telephone 571 The source telephone 570 is notified of the call (step J23 to step J30). When the telephone 571 is off-hook, an IP packet indicating the telephone communication start is notified to the source telephone 570 (steps J32 to J40), and telephone communication is started.

By the above, the terminal-to-terminal communication connection control procedure between the telephone 570 and the telephone 571 is completed, and a telephone call can be made between the telephone 570 and the telephone 571.

At the end of the telephone call, the call release notification of the telephone is sent from the telephone 570 to the switch 557 (step J42 in Fig. 189), and the call release completion notification is returned from the telephone switch 557 to the telephone 570 (step). J43). Subsequently, the exchange 557, the exchange 559, the gateway 551, the telephone management server 549-1, the telephone management server 549-5, the gateway 554, the exchange 562, and the exchange 561 ), The call release notification and the call release completion notification are sequentially transmitted and received between the telephones 571 to release the connection (steps J44 to J59).

The control data transmitted / received to the switchboard or the telephone management server of the step correspond to the connection control message of the common line signal. Corresponds to, ANM message, REL message, RLC message.

The above "communication connection control-1 between telephones" is summarized as follows. That is, as a communication connection control method between two telephones connected to a public switched telephone network using an IP transmission network as a relay network, a calling telephone uses a calling telephone number, a carrier identification code, and a destination telephone number to make a call. By referring to the "input line table inside the IP transport network" in the IP transport network-side gateway specified by the operator code, the signal station code of the input gateway for connecting to the IP transport network is obtained. The input gateway obtains the IP address of the output gateway for connecting the call line from the inside of the IP transport network to the public switched telephone network by referring to the "output circuit table outside the IP transport network" in the gateway using the destination telephone number as a parameter. The IP packet including the source telephone number and the destination telephone number is transmitted to the output gateway toward the obtained IP address. The output gateway sends a call to the public switched telephone network based on the source telephone number and the destination telephone number included in the IP packet received above, and transmits the call to the destination telephone after the exchange.

Alternatively, " output line information outside the IP transport network " is queried to the telephone number server and the telephone number server answers. "Input line information inside the IP transport network" is a signal station code of a gateway having an NNI communication line outside the IP transport network, and "Output line information outside the IP transport network" is a gateway having an NNI communication line outside the IP transport network. IP address.

<< Communication connection control between telephones -2 >>

This will be described with reference to FIGS. 190 and 191.

It is an example of telephone connection from the source telephone 570 having the telephone number "03-1111-2222" to the telephone 572 of the destination having the telephone number "092-555-6666". When the telephone 570 dials " 00XY-092-555-6666 " to request a telephone connection (step K01 in Fig. 190), the trainer 557 responds (step K02). The exchange 557 finds an exchange 558 connected to the gateway 550 containing line information assigned with "00XY" using the carrier identification code "00XY" included in the dialed information, and The source telephone numbers "03-1111-2222" and "00XY-092-555-6666" acquired at the time of dialing are transmitted to the exchange 558 (step K03).

The exchange 558 transmits the source telephone number "03-1111-2222" and the destination telephone number "092-555-6666" to the gateway 550 including the line information (step K04) and includes the line information. The gateway 550 refers to the IP transmission network input line table 584 in the gateway 550 containing the line information to the gateway for connecting the communication line to the telephone whose destination telephone number is "092-555-6666". One telephone number " 03-4444-4000 " is found as the access information, and the switch 558 is notified (step K05). Next, the exchange 558 finds an exchange connected to the gateway telephone number "03-4444-4000", and in this case, finds the exchange 560 and finds the telephone number as access information to the gateway obtained by the above procedure. Information including 03-4444-4000 ", source telephone number" 03-1111-2222 ", and destination telephone number" 092-555-6666 "is transmitted to the exchange 560 (step K06). Switch 560 passes "03-1111-2222" and destination telephone number "092-555-6666" past UNI communication line 580 to gateway 552 to which telephone number "03-4444-4000" is assigned. Is transmitted (step K07). The gateway 552 reports to the exchange 560 that it has received these two telephone numbers (step K08).

The gateway 552, upon receiving the above information, retrieves the IP transmission network output line table 587 (FIG. 187), and the gateway of the communication counterpart for connecting the communication line with the destination telephone number " 092-555-6666 " as a parameter. In the case, the IP address "10.240.241.1" of the gateway 553 is acquired, and an IP packet including the obtained source telephone number "03-1111-2222" and the destination telephone number "092-555-6666" is formed. . The source IP address of the formed IP packet is an IP address assigned to the gateway 552 (known by the gateway 552 itself), and the destination IP address is the IP address " 10.240.241.1 " of the acquired gateway 553. to be.

Further, in the process of the above-described gateway 552 discovering the IP address of the gateway 553, the gateway 552 presents the destination telephone number "092-555-6666" from the gateway 552 to the telephone number server 594, and the gateway ( A " inquiry IP packet " asking the value of the IP address of 553 can be sent (step KK1 in FIG. 190), and a reply can be obtained from the telephone number server 594 (step KK2 in FIG. 190), or the telephone number server. The content of 594 may be previously transmitted inside the gateway 552, and may be used as an IP transmission network output circuit table (however, steps KK1 and KK2 are optional).

Next, the IP packet formed above and sent out from the gateway 552 passes through the network node device 543 and the router 546-2 and passes through the telephone management server 549-2 (step K09) and the router 546. -3) via the router 546-4 and the telephone management server 549-4 (step K10), the gateway 553 is reached via the network node device 545 (step K11). Gateway 553 then communicates information including source telephone number "03-1111-2222" and destination telephone number "092-555-6666" to exchange 563 over UNI communication line 581. (Step K12). The exchange 563 returns to the gateway 553 that these two telephone numbers have been received (step K13).

The exchange 563 sends a call setup request including the source telephone number "03-1111-2222" and the destination telephone number "092-555-6666" to the exchange 564 (step K14), and the exchange 564 Returns to the exchange 557 that the call setting request has been received (steps K16 to K22). The switch 564 calls the telephone 572 (step K15), and the telephone 572 notifies the switch 564 that the telephone call is being made (step K24). The exchange 564 notifies the source telephone 570 that the destination telephone 572 is calling (steps K25 to K32). When the telephone 572 is off-hook notified (step K33), the telephone communication start possibility notification is notified to the transmission telephone 570 (step K35-step K42), and telephone communication starts.

By the above, the terminal-to-terminal communication connection control procedure between the telephone 570 and the telephone 572 is completed, and a telephone call can be made between the telephone 570 and the telephone 572.

At the end of the call of the telephone, the call release notification of the telephone is sent from the telephone 570 to the switch 557 (step K44 in Fig. 191), and the call release completion notification from the switch 557 is returned to the telephone 570 ( Step K45). This call release notification and call release completion notification release the connection between the telephone 570 and the switch 557. Subsequently, the exchange 557, the exchange 560, the gateway 552, the telephone management server 549-2, the telephone management server 549-4, the gateway 553, the exchange 563, the exchange ( 564, the phone release notification and the call release completion notification are sequentially transmitted and received between the telephone 572, thereby releasing the telephone call (steps K46 to K61).

Summarizing the above " communication connection control-2 between telephones ", a method of controlling an end-to-end communication connection for communicating from a telephone connected to a public switched telephone network to another telephone connected to a public switched telephone network via an IP transport network is outlined. This is similar to the communication connection control-1 between telephones. The main difference is that "input line information inside the IP transport network" is a telephone number of a gateway having a UNI communication line outside the IP transport network, and "output line information outside the IP transport network" is a gateway having a UNI communication line outside the IP transport network. This is called a local IP address.

<< Communication connection control between telephones -3 >>

This is an example of dialing from the source telephone 570 having the telephone number "03-1111-2222" to the telephone 598 of the destination having the telephone number "093-555-6666".

In this example, if the telephone 570 dials " 00XY-093-555-6666 " to request a dial-up connection, and the exchange 558 requests the gateway 550 containing line information, the gateway 550 is internally located. IP transport network input line table 584 is used, so that exchange 558 uses signal station code "# 2222 " as access information to the gateway for connecting a communication line to a telephone having a destination telephone number of " 093-555-6666 ". The switch 559 and the gateway 551 are connected via the NNI communication line 577 here.

Next, the gateway 551 inquires the IP transmission network output line table 586 or the telephone number server 593 inside the gateway 551, and connects the communication line to the telephone having the destination telephone number "093-555-6666". IP address of the gateway 553 is obtained, and an IP packet including a source telephone number "03-1111-2222" and a destination telephone number "093-555-6666" is formed. The formed IP packet is sent out from the gateway 551 to the router 546-1, the telephone management server 549-1, the router 546-1, the router 546-5, and the telephone management server 549-5. The gateway 553 is reached through the router 546-5 and the network node device 545.

Thereafter, the terminal-to-terminal connection information including the source telephone number "03-1111-2222" and the destination telephone number "093-555-6666" obtained from the IP packet passes the switch 563 and the switch 566 to the telephone 598. ), The terminal-to-terminal communication connection control between the telephone 570 and the telephone 598 is completed.

Although the above "communication connection control-3 between telephones" and "communication connection control-1 between telephones" are similar, in contrast, "input line information into an IP transport network" has an NNI communication line outside the IP transport network. Signaling station code of the gateway, " output line information outside the IP transmission network " is an IP address to the gateway having a UNI communication line outside the IP transmission network.

<< Communication connection control between telephones-4 >>

This is an example of dialing from the source telephone 570 having the telephone number "03-1111-2222" to the telephone 597 of the destination having the telephone number "07-3333-4444".

In this example, the telephone 570 dials " 00XY-07-3333-4444 " to request a dial-up connection, so that the exchange 558 requests the gateway 550 containing the line information, and inside the gateway 550. IP transport network input line table 584 is used, so that exchange 558 uses telephone number " 03-4444- " as access information to a gateway for connecting a communication line to a telephone having a destination telephone number of " 07-3333-4444 ". Acquire 4000 ". Next, the gateway 552 queries the IP transmission network output line table 587 or the telephone number server 594 inside the gateway 552, and connects the communication line to the telephone having the destination telephone number "07-3333-4444". The IP address of the gateway 554 is obtained, and an IP packet including the source telephone number "03-1111-2222" and the destination telephone number "07-3333-4444" is formed. The formed IP packet is transmitted from the gateway 552 to transmit the network node apparatus 543, the router 546-2, the telephone management server 549-2, the router 546-2, the router 546-1, and the router. 546-5, the phone management server 549-5, and the router 546-5 to reach the gateway 554.

Thereafter, the terminal-to-terminal connection information including the source telephone number "03-1111-2222" and the destination telephone number "07-3333-4444" obtained from the IP packet passes through the switch 562 and the switch 565, and the telephone 597. ), The terminal-to-terminal communication connection control between the telephone 570 and the telephone 597 is completed.

The above "communication connection control-4 between telephones" and "communication connection control-1 between telephones" are similar, but in contrast, "input line information into the IP transmission network" has a UNI communication line outside the IP transmission network. The telephone number of the gateway, " output line information outside the IP transport network " is an IP address to the gateway having an NNI communication line outside the IP transport network.

<< Communication connection control between phones-5 >>

This is an example of dialing a telephone 573 (however, the telephone number is "045-777-8888") connected to the media router 591 from the source telephone 570 having the telephone number "03-1111-2222". .

When the telephone 570 dials " 00XY-045-777-8888 " to request a telephone connection (step L01 shown in FIG. 192), the switch 557 responds (step L02), and the switch 557 dials the dial. Using the carrier identification code "00XY" included in the received information, the switch 558 connected to the gateway 550 containing the line information to which "00XY" is assigned is found, and the source telephone obtained at the time of dialing. The numbers "03-1111-2222" and "00XY-045-777-8888" are transmitted to the exchange 558 (step L03).

The exchange 558 transmits the source telephone number "03-1111-2222" and the destination telephone number "045-777-8888" to the gateway 550 including the line information (step L04), and the gateway 550. Finds the telephone number "03-4444-4000" as access information to the gateway for connecting the communication line to the telephone whose destination telephone number is "045-777-8888", referring to IP transmission network input line table 584. A notification is made to 558 (step L05). Next, the switch 558 finds the switch 560 which connects to the gateway telephone number "03-4444-4000", and obtains the telephone number "03-4444-4000" and the caller telephone number "03-" obtained by the above procedure. Information including 1111-2222 "and the destination telephone number" 045-777-8888 "is transmitted to the exchange 560 (step L06). Switch 560 passes "03-1111-2222" and destination telephone number "045-777-8888" past communication line 580 to gateway 552 to which telephone number "03-4444-4000" is assigned. It transmits (step L07), and the gateway 552 returns to the exchange 560 that it has received at least these two telephone numbers (step L08).

Next, the gateway 552 forms an IP packet including the source telephone number "03-1111-2222" and the destination telephone number "045-777-8888" obtained by the above communication connection control. The source IP address of the IP packet is an IP address assigned to the gateway 552 (known by the gateway 552 itself), and the destination IP address is a communication counterpart for connecting a communication line, in this case, the media router 591. IP address "10.241.1.1", and the destination telephone number "045-777-8888" is found as a parameter from the IP transmission network output line table 587.

The telephone call connection request IP packet thus formed and sent out from the gateway 552 includes the network node apparatus 543, the router 546-2, the telephone management server 549-2, the router 546-2, and the router ( 546-3, the telephone management server 549-3, the router 546-3, and the network node device 544, and reach the media router 591 (steps L10 to L16). The media router 591 returns to the exchange 557 that the telephone call connection request has been received (step L20 to step L25), and the media router 591 calls the telephone 573 (step L18). When returning (step L27), the media router 591 notifies the source telephone 570 that the destination telephone is being called (step L29 to step L35). When the telephone 573 is off-hook (step L36), a response indicating that telephone communication can be started is notified to the source telephone 570 (steps L38 to L44), and telephone communication is started.

By the above, the terminal-to-terminal communication connection control procedure between the telephone 570 and the telephone 573 is completed, and a telephone call can be made between the telephone 570 and the telephone 573.

At the end of the telephone call, the call release notification of the telephone is sent from the telephone 570 to the switch 557 (step L45), and the call release completion notification is returned from the telephone switch 557 to the telephone 570 (step K46). This call release notification and call release completion notification release the connection between the telephone 570 and the switch 557. Subsequently, calls are made between the switch 557, the switch 560, the gateway 552, the phone management server 549-2, the phone management server 549-3, the media router 591, and the telephone 573. The release notification and the call release completion notification are sequentially transmitted and received to release the connection (steps J47 to J60).

The above "communication connection control-5 between telephones" is similar to "communication connection control-1 between telephones", and a major contrast is that the telephone connection line is a telephone connected to the media router.

<< Communication connection control between phones-6 >>

A description with reference to FIG. 193 is provided. Reference numeral 540-1 denotes an IP transmission network, reference numerals 550-1 and 554-1 denote gateways, and reference numeral 1000 denotes an "output circuit information server." Other devices, telephones, public switched networks, and the like are the same as those shown in FIG. 185, telephones, and the like, and are denoted by the same numbers. This embodiment is characterized by using the input line information server 1000 including the IP transmission network input line table 584 instead of the gateway 550 containing the line information (see FIG. 185). Steps J04 and J05 of FIG. Instead, step J04x and step J05x in FIG. 194 are used.

The input line information server 1000 is provided with a carrier identification code "00XY" that can be identified from the public switched telephone network 555, and a signal station code for identifying from the public switched telephone network 555. This is an example of telephone connection from the source telephone 570 having the telephone number "03-1111-2222" to the telephone 571 of the destination having the telephone number "06-3333-4444". A description with reference to FIG. 194 is provided.

When the telephone 570 dials " 00XY-06-3333-4444 " (step J01 in Fig. 194), the switch 557 confirms the call (step J02), and the switch 557 dials the dialed information. Using the carrier identification code "00XY" included in the message, the switch 558 connected to the input line information server 1000 to which "00XY" is assigned is found, and the source telephone number "03-" obtained at the time of dialing. 1111-2222 "and" 00XY-06-3333-4444 "are transmitted to the exchange 558 (step J03). The exchange 558 transmits the source telephone number "03-1111-2222" and the destination telephone number "06-3333-4444" to the input line information server 1000 (step J04x), and the input line information server 1000 Refer to the IP transmission network input line table 584 in the input line information server 1000, and use the telephone number of the destination telephone as a parameter, that is, the communication line to the telephone having the destination telephone number "06-3333-4444". As the access information to the gateway for connection, the gateway has an NNI interface, finds that the signal station code of the gateway as the signal station is "# 2222", and returns to the exchange 558 (step J05x). By performing steps J06 to J40, a terminal-to-terminal communication connection control procedure is established between the telephone 570 and the telephone 571, whereby a telephone call can be made between the telephone 570 and the telephone 571. In the same manner, the terminal-to-terminal communication connection control procedure between the telephones 570 and 557, 597, 598, and 573 can be performed.

<< Embodiment of Network Node Device >>

A network node device used in the method for controlling communication between terminals is described with reference to FIG. 195.

Reference numeral 540-1 denotes an IP transmission network, reference numerals 543-1 and 545-1 denote network node devices, reference numerals 552-1 and 554-1 denote gateways, reference numerals 547-1 and 548-1 denote relay devices, respectively. It is connected by a communication line. The IP address " a " is assigned to the gateway 552-1, and the IP address " b " is assigned to the gateway 554-1, and the communication of the gateway 552-1 side of the network node device 543-1 is performed. IP address "x" is given to the contact with a line, and IP address "y" is given to the contact with the communication line of the gateway 554-1 of the network node apparatus 545-1. 543-1T is an address management table which holds the above four sets of IP addresses "a", "b", "x", and "y". 545-1T is an address management table holding the four sets of IP addresses "b", "a", "y", and "x".

The PCK-1 of the IP packet sent from the gateway 552-1 to the gateway 554-1 has a source IP address of "a", a destination IP address of "b", and the network node apparatus 543-1. If so, address management table 543-1T is referred to. In this example, among the internal information "a", "b", "x", and "y", three IP addresses "a", "b", and "x" are three pieces of IP packet PCK-1 inside. Since the IP address coincides with the IP address, another IP address " y " in the address management table 543-1T is fetched to perform IP encapsulation to give an IP header, thereby forming a new IP packet, PCK-2. IP packet PCK-2 is sent from the network node device 543-1 to the communication line and passes through the routers 547-1 and 548-1 to the network node device 545-1, where the IP encapsulation De-encapsulation is performed to remove the assigned IP header, and the IP packet PCK-3 is restored and sent to the gateway 554-1 through the communication line. The address management table 545-1T is used for IP packet transmission in the reverse direction.

The network node devices 543-1 and 545-1 have a function of IP encapsulation and decapsulation, and have an address management table for this purpose. The IP address of the gateway is characterized in that it is registered and held in the address management table of the network node devices 543-1 and 545-1.

<< Another embodiment of network node device >>

Another embodiment of the network node apparatuses 543-2 and 545-2 will be described with reference to FIG. 196.

Reference numeral 540-2 denotes an IP transport network, reference numerals 543-2 and 545-2 denote network nodes, reference numerals 552-2 and 554-2 denote gateways, reference numerals 547-2 and 548-2 denote relay devices, respectively. It is connected by a communication line. IP address "a" is assigned to gateway 552-2, and IP address "b" is assigned to gateway 554-2, respectively. 543-2T is an address management table holding the IP address " a " and 545-2T holding the IP address " b ".

The IP packet PCK-11 sent from the gateway 552-2 to the gateway 554-2 arrives at the network node device 543-2 having a source IP address of "a" and a destination IP address of "b". Refer to address management table 543-2T. In this example, since the internal information "a" coincides with the IP address of the sender inside the IP packet PCK-11, it can be understood that there is a permission to transmit the IP packet PCK-11 into the IP transmission network 540. Let packet PCK-11 be the IP packet PCK-12 as it is. The IP packet PCK-12 is transmitted from the network node device 543-2 to the communication line, and reaches the network node device 545-2 through the routers 547-2 and 548-2. Here, since the destination IP address " b "of the IP packet PCK-12 is recorded in the address management table 545-2T, the IP packet PCK-12 is the IP packet PCK-13 as it is, passing through the communication line as a gateway 554-2. Is sent to. The network node devices 543-2 and 545-2 accept IP packets inside the IP transport network 540-2 to confirm the permission, or the IP address “b” exists outside the IP transport network 540-2. You can see that. The IP address of the gateway is characterized by being registered and held in the address management tables of the network node devices 543-2 and 545-2.

To summarize the functions of the above network node device, in the present embodiment, when the network node device receives an IP packet from outside the IP transport network to the inside of the IP transport network, the type of IP encapsulation for newly granting an IP header is not performed. There are two types of types. The IP address of the gateway is registered and held in the address management table of the network node device.

13. Thirteenth embodiment in which control line and voice line are separated and connected to public switched telephone network:

A method of separating the control communication line from the voice communication line and controlling the telephone-terminal communication connection via the IP transmission network and the public switched telephone network (PSTN) will be described.

In Fig. 197, reference numeral 1500 denotes an IP transmission network, reference numeral 1501 denotes a public switched telephone network, reference numeral 1502 denotes a gateway having an encapsulation function, reference numeral 1503 denotes a relay gateway, reference numerals 1508 and 1520, a telephone exchange, and reference numeral 1518 a relay switch. Reference numeral 1519 denotes a subscriber switch, reference numeral 1505 denotes a control communication line using a common line signal system, and reference numeral 1506 denotes a voice communication line. Reference numeral 1507 denotes a control IP communication line, and reference numeral 1509 denotes a voice IP communication line. Reference numerals 1544 and 1547 denote network node devices, reference numeral 1570 denotes a surrogate telephone server, reference numeral 1571 denotes a telephone management server, reference numeral 1572 denotes a telephone number server, reference numeral 1573 denotes a table management server, reference numerals 1521, 1522, 1523, Each 1524 is a router. Reference numeral 1513 denotes a relay control unit (STP), and reference numeral 1516 denotes a voice control unit.

Some of the internal resources (devices or servers) of the IP transport network shown in FIG. 197 may correspond to some of the internal resources of the IP transport network shown in FIG. 128 or 170, and the telephone 1508, the media router 1560, and the network node may correspond. The device 1544, the surrogate telephone server 1570, the telephone management server 1571, the telephone number server 1572, the table management server 1573, and the network node device 1547 are each a telephone 1208 and a media router 1201. ), The network node apparatus 1244, the proxy telephone server 1270, the telephone management server 1271, the telephone number server 1272, the table management server 1273, and the network node apparatus 1247.

<< Function of Relay Control Unit >>

In the present invention, a point of a common line signal system is represented by a signal station and a point code is represented by a "signal station address". The relay control unit 1513 inside the relay gateway 1503 is a relay signal station (STP) of a common line signaling system, and is assigned a signal station address "PC-3" when viewed from the public switched telephone network 1501. The relay control unit 1513 manages the signal station address management table 1527 (FIG. 208), and can retrieve the signal station address of the exchange in the public switched telephone network 1501 by searching the signal station address management table. The relay gateway 1503 has the same rules as the generation rule of the line number "CIC-n" or the signal link selection "SLS-n" to be written in the signal unit to be transmitted to the NNI communication line 1505 with the same rules as that of the public switched telephone network 1501. It is decided.

The relay control unit 1513 is assigned an IP address "GW03", and various messages (IAM, ACM, CPG, ANM, REL, RLC, etc.) of telephone call control stored in an IP packet sent from the control IP communication line 1507. Is converted into various messages (IAM, ACM, CPG, ANM, REL, RLC, etc.) stored in the signal unit of the common line signaling method, and transmitted to the control communication line 1505. Further, in the reverse direction, the relay control unit 1513 converts various messages for telephone call control stored in the signal unit sent from the control communication line 1505 into messages stored in the IP packet and transmits them to the control IP communication line 1507. Have The IP address " GW03 " and signal station code " PC-3 " assigned to the relay control unit 1513 are also IP addresses and signal station codes assigned to the relay gateway 1503.

<< Function of voice control unit >>

The voice control unit 1516 can transmit the voice stored in the IP packet sent from the voice IP communication line 1509 in the public switched telephone network 1501, for example, a primary group interface (PRI) of ISDN. , 23B + D) is converted into an audio frame suitable for the data communication path and transmitted to the audio communication line 1506. In addition, the voice controller 1516 has a function of converting a voice frame sent from the voice communication line 1506 of the public switched telephone network 1501 into an IP packet format and transmitting it to the voice IP communication line 1509. The voice control unit has an IP address for transmitting and receiving voice IP packets therein and is used for setting a media path connection table.

<< phone number server >>

When the telephone number server 1572 asks for a telephone number, the telephone number server 1572 answers an IP address for communicating with the telephone having the telephone number in question. In the case where the telephone communication destination is the relay gateway, the IP address value assigned to the relay gateway is returned. In the case where the telephone communication destination is the gateway having the encapsulation function, the IP address of the media router connected to the gateway is returned.

<< connection phase >>

It is an example of carrying out telephone communication from the telephone 1508 to the telephone 1520. In this embodiment, the IP address " EA81 " of the surrogate telephone server 1570 is open to the user of the IP transport network 1500, and the media router 1560 holds the IP address " EA81 ". When the handset of the telephone 1508 is lifted, a call signal is transmitted to the media router 1560 (step N01 in FIG. 198), and the media router 1560 confirms the telephone call (step N02). Next, the media router 1560 sets the sender IP address to the IP address " EA1 " of the media router 1560, and the destination IP address to the external IP address " EA81 " Telephone number " TN-1 " of 1508, telephone number " TN-2 " of telephone 1520 as a destination, UDP port number " 5006 " An IP packet 1530 (FIG. 199) including the additional information " Info-2 " is formed and transmitted to the network node device 1544 (step N03). The payload portion of the IP packet 1530 is a UDP packet, which is an example in which both its source and destination port numbers are "5060".

The network node device 1544 inputs an external IP packet 1530, forms an internal IP packet 1531 (FIG. 200) by applying an IP encapsulation technique described in another embodiment, and forms an IP packet 1531. It sends to the alternative telephone server 1570 whose internal IP address is "IA81" (step N04). When the proxy telephone server 1570 receives the IP packet 1531, the IP phone 1532-1 including the IP address "EA1, IA1, EA81, IA81" included in the IP packet 1531 in the payload portion. 201, it forms and transmits to the telephone management server 1571 (step N05). The alternative telephone server 1570 uses the IP address " IA91 " of the telephone management server 1571 held in advance.

<< Formation of CIC Management Chart >>

The telephone management server 1571 receives the IP packet 1532-1, and records the IP address "IA91" of the telephone management server 1571 and the procedure segment in the record of the CIC management table managed by the telephone management server 1551. ) "IAM", source telephone number "TN-1", destination telephone number "TN-2", external IP address "EA1" and internal IP address "IA1" of the media router 1560, IP packet 1532-1. ) The internal voice communication port number "5006", the external IP address "EA81" of the proxy telephone server 1570, the internal IP address "IA81", and the writing time (year, month, date, minute, second) "St-2" are written (FIG. 202). CIC management table 1571-1).

Next, the telephone management server 1571 shows the IP number 1532-2 (FIG. 203) asking the destination telephone number "TN-2" to the telephone number server 1572 (step N06). 1572 stores the IP address " GW03 " of the device connected to the telephone 1520 in the IP packet 1532-3 (FIG. 204), and responds (step N07). In addition, the apparatuses connected to the telephone 1520 are examples of the relay control unit 1513 inside the relay gateway 1503.

<< Management of line number >>

The telephone management server 1571 adds the IP address "GW03" of the relay control unit 1513 acquired from the telephone number server 1572 to the CIC management table 1571-1 (FIG. 202), and also the IP address of the telephone management server 1571. For the set of "IA91" and the IP address "GW03" of the relay control unit 1513, the CIC number "C1C-2" is determined according to the rules defined by the telephone management server 1571, and is written in the CIC management table. This state is shown in the record of CIC management table 1571-2 (FIG. 205).

Next, the telephone management server 1571 forms an IP packet 1534 (see FIG. 206, IAM packet) from the IP packet 1532-1 (FIG. 201) with reference to CIC management table 1571-2 (FIG. 205). The IP packet 1534 is transmitted to the relay control unit 1513 (step N09). Here, the destination IP address of the IP packet 1534 is the IP address "GW03" of the relay control unit 1513.

<< Operation of Relay Control Unit >>

When the relay control unit 1513 receives the IP packet 1534 (FIG. 206) (step N09), from the IP packet 1534, the source IP address "IA91", the destination IP address "GW03", and the line number "CIC-2". ", Order classification" IAM ", source telephone number" TN-1 ", destination telephone number" TN-2 ", external IP address" EA1 "and internal IP address" IA1 "of media router 1560, port for voice communication The number " 5006 ", the external IP address " EA81 " and the internal IP address " IA81 " Write with "St-3".

The relay control unit 1513 also retrieves the signal station address management table 1527 (FIG. 208), presents the telephone number " TN-2 " of the destination telephone 1520, and manages the telephone 1520 of the exchange 1519. Acquire the signal station address "PC-19". In addition, the relay control unit 1513 determines the line number "CIC-3" and the signal link selection "SLS-3" in accordance with the rules previously determined with the public switched telephone network 1501. The relay control unit 1513 stores the signal station address "PC-3" of the relay control unit 1513, the acquired "PC-19", the signal link selection "SLS-3", and the line number "CIC-3". Together with the media path identifier " MP-7 ", it is written as a new record of the address connection table 1525, and as a result, the address connection table is as shown in 1525-1 (FIG. 209).

Subsequently, the relay control unit 1513 sets the signal station address "PC-3", the acquired "PC-19", the line number "CIC-3", the signal link selection "SLS-3", and the IP packet. A signal unit 1535 including the message " IAM " and the parameter " Para-2 " obtained from 1534 is formed (FIG. 210), and transmitted to the control communication line 1505 (step N10).

<< Linkage between relay control unit and voice control unit >>

The relay control unit 1513 informs the media path identifier "MP-7", the internal IP address "IA-1" for encapsulation, the external IP address "EA1" of the media router 1560, and the port number "5006" for voice communication. The voice control unit 1516 is notified via the line 1515 (step 1513-1 in FIG. 211), and the voice control unit 1516 writes the notified information as a record of the media path connection table 1528, and completes writing. Report (step 1516-1). The media path identifier is used to identify the voice communication path used for telephone calls (connection / call / release) between two telephones. The record of the media path connection table 1528-1 (FIG. 214) shows before writing, and the media path connection table 1528-2 (FIG. 215) shows the writing result. In addition, the voice control unit 1516 determines a logical communication line for transmitting voice from the voice control unit 1516 to the voice communication line 1506, and the logical communication line identifier "CH-1" (transmission channel: Channel-S). ) Is written as a record of the media path connection table 1528-2.

<< Switch Network Behavior and ACM Messages >>

The exchange 1518 receives the signal unit 1535 via the control communication line 1505 (step N10), and then transmits the signal unit 1535 to the exchange 1519 (step N11). The exchange 1519 receives the signal unit 1535 and checks whether the destination telephone number " TN-2 " contained therein can be reached, and if the call is possible, notifies the incoming call notification to the telephone 1520 (step N12). Further, a signal unit 1538-1 (FIG. 218) informing the reception of the signal unit 1535 is formed and returned, and the signal unit passes through the exchange 1518 (step N13) to the relay control unit 1513. (Step N14). The relay control unit 1513 obtains address information for forming an IP packet with reference to the address connection table 1525-1 (FIG. 209) based on the received label information of the signal unit 1538-1, and the IP A packet 1551 (ACM message, see Fig. 219) is formed and an IP packet 1551 is transmitted to the telephone management server 1571 (step N15).

The telephone management server 1571 retrieves the line number "CIC-2" and the sequence division "ACM" from the received IP packet 1551, and examines the CIC management table 1571-2 (FIG. 205) held by the telephone management server 1571. A record having its own IP address " IA91 ", its partner IP address " GW03 " and the line number " CIC-2 " Next, the telephone management server 1571 forms an IP packet indicating that the ACM message has been received and notifies the media router 1560 (steps N17, N18, N19).

<< Media Pass Connection Table >>

After completing step N10, the relay control unit 1513 attaches the media path identifier "MP-7" to the voice control unit 1516 and requests an IP address and a port number (step 1513-2 in FIG. 212). 1516 is an internal IP address " IA1 " of the IP packet " EA3 " and the UDP packet for encapsulation of the IP packet formed by the voice control unit 1516 and sent to the voice IP communication line 1509 inside the IP transmission network 1500. The port number "5008" is returned to the relay control unit 1513 (step 1516-2) The voice communication path identified by the media path identifier is assigned to the IP addresses ("IA3, EA3,... And a plurality of voice communication paths can be determined by a combination of port numbers "5004, 5006, ...". The voice control unit 1516 also secures logical voice communication lines received from the switch 1518. The identifier "CH-2" (receive channel: denoted as Channe1-R) is determined. It is recorded in the record in the connection table 1528-3 (FIG. 216).

The relay control unit 1513 receives the internal IP address "IA1", the source external IP address "EA3" and the port number "5008" of the UDP packet from the voice control unit 1516 in the voice control unit 1516, and receives the IP address "EA3". &Quot; Internal IP address " IA3 " corresponding to " &quot; is written to CIC management table 1513-1 (FIG. 207), and the result is the same as CIC management table 1513-2 (FIG. 217) (the address of the alternative telephone management server is not included). ). The relay control unit 1513 holds one or more internal IP addresses for the voice control unit in advance, and sets one of the internal IP addresses "IA3".

<< Sending CPG Messages >>

When the telephone 1520 reports to the switch 1519 that the telephone is being called (step N20), the switch 1519 forms and transmits a signal unit (CPG message) indicating that the telephone is being called, and the signal unit switches 1518. ), The relay control unit 1513 is reached (step N22). The relay control unit 1513 obtains address information for forming an IP packet with reference to address connection table 1525-1 (FIG. 209) based on the received label information of the signal unit, and CPG message 1552 in the form of an IP packet. 220, the IP packet is transmitted to the telephone management server 1571 (step N23). The telephone management server 1571 notifies the telephone 1508 via the media router 1560 of the notification informing that the telephone call is in progress (steps N25 to N28). When the relay control unit 1513 forms the CPG message, from the CIC management table 1513-2 (FIG. 217), the source external IP address "EA3", the internal IP address "IA3", and the port number "5008" of the UDP packet in the voice control unit. Is obtained and written in the CPG message 1552. The telephone management server 1571 can extract the external IP address "EA3", the internal IP address "IA3", and the port number "5008" from the received CPG packet 1552, and write them in the management table 1571-2 (FIG. 205).

<< Sending ANM Message >>

Next, when the user of the telephone 1520 responds to the telephone call (step N30), the exchange 1519 forms and transmits a signal unit (ANM message) informing the response, and the signal unit passes through the exchange 1518. (Step N31), the relay control unit 1513 is reached (step N32). The relay control unit 1513 forms an ANM message 1553 (FIG. 221) in the form of an IP packet with reference to address connection table 1525-1 (FIG. 209) based on the received label information of the signal unit. 1553 is transmitted to the telephone management server 1571 (step N33). The telephone management server 1571 then notifies the telephone 1508 of the call response notification via the media router 1560 (steps N35 to N38). That is, the IP packet 1554 (FIG. 223) is sent from the telephone management server 1571 to the surrogate telephone server 1570 (step N35), and the IP packet (from the surrogate telephone server 1570 to the network node device 1544). 1555 (FIG. 224) is sent (step N36), and IP packet 1556 (FIG. 225) is sent from network node device 1544 to media router 1560 (step N37).

When the relay control unit 1513 forms the ANM message, from the CIC management table 1513-2 (FIG. 217), the source external IP address "EA3", the internal IP address "IA3" and the port number "5008" of the UDP packet in the voice control unit. Is obtained and written in the ANM message 1553. The telephone management server 1571 can retrieve the external IP address "EA3", the internal IP address "IA3", and the port number "5008" from the received response packet 1553 and write them in the CIC management table 1571-2 (FIG. 205). have.

<< write timing to CIC management table 1571 >>

The timing at which the telephone management server 1571 retrieves the external IP address "EA3", the internal IP address "IA3", and the port number "5008" and writes them into the CIC management table 1571-2 is the step N23 in which the CPG message was received in the above description. Or only one of step N33 in which the ANM message is received.

<< Setting of IP Communication Record by Relay Control Unit >>

In step N33, the relay control unit retrieves the IP addresses "EA3", "EA1", "IA3", and "IA1" from the inside of the record of the CIC management table 1513-3 (FIG. 222) and transmits it to the table management server 1576 (step). N41), the table management server 1576 sets as IP communication records " EA3, EA1, IA3, IA1 " in the address management table inside the network node device 1547 (step N42). Incidentally, the type of record in the address management table and the address setting method for the record are described in another embodiment.

<< Setting of IP Communication Records by the Telephone Management Server >>

Similarly, the telephone management server 1571 retrieves the IP addresses " EA1 ", " EA3 ", " IA1 ", and " IA3 " from the inside of the record of the CIC management table in step N35, and sends it to the table management server 1573 ( Step N43), the table management server 1573 sets as IP communication records " EA1, EA3, IA1, IA3 " in the address management table inside the network node device 1544 (step N44).

<< Communication phase >>

The telephone communication between the user of the telephone 1508 and the telephone 1520 is the same steps as described in the other embodiments, and the IP communication records of the address management table inside the network node device 1544, that is, "EA1, EA3, IA1, A record of " IA3 " and an IP communication record " EA3, EA1, IA3, IA1 &quot; of the address management table inside the network node device 1547 are used.

The voice of telephone 1508 is digitized and carried in the payload of IP packet 1561 (FIG. 226). Here, the destination address and the UDP port number obtained in the connection phase are used. That is, the source address is the IP address " EA1 " of the media router 1560, the destination address is the IP address " EA3 " in the voice control unit 1516 to which the destination telephone 1520 is connected, and the media router is used for voice transmission. The UDP port number used is "5006", and the UDP port number used by the voice control unit 1516 for voice transmission is "5008".

An analog voice is sent from the telephone 1508, and the voice is digitized at the media router 1560 to be sent to the network node device 1544 as a voice IP packet 1561 (FIG. 226), and the IP communication record " EA1 at the network node device. IP3 encapsulation is performed using EA3, IA1, and IA3 "to form IP packet 1562 (FIG. 227), and reach network node device 1547 via router 1524 via an IP communication line. Here, the IP communication record " EA3, EA1, IA3, IA1 " is used to decapsulate to form an IP packet 1563 (FIG. 228), and the IP packet 1563 storing the digitized voice is stored in the IP voice control unit 1516. To reach. The voice controller retrieves the source IP address "EA1 ", the source port number " 5006 ", the destination IP address " EA3 " and the destination port number " 5008 " included in the IP packet 1563, and the media path connection table 1528-. See 3 (FIG. 216). A media path record with a source IP address " EA1 ", a source port number " 5006 ", a destination IP address " EA3 " and a destination port number " 5008 " is used, so that the digitized voice in the IP packet 1563 is a voice communication line ( A voice frame 1564 (FIG. 229) in the form transmitted at 1506 is converted, and the voice frame 1564 reaches the switch 1519 via the switch 1518, and the voice is output from the telephone 1520. . The voice stored in the voice frame sent from the phone 1520 is sent in the reverse direction as described above to reach the phone 1508.

<< liberation phase >>

When the user of the telephone 1508 notifies the telephone communication release (step N50 of FIG. 198), the media router 1560 sends a telephone call release notification to the telephone management server 1571 (steps N51 to N53), and the telephone management server. 1531 returns the completion of the release to the media router 1560 (steps N64 to N66). In addition, the telephone management server 1571 sends an IP packet 1565 (FIG. 230) informing the release of the telephone call to the relay control unit 1513 (step N55), and the relay control unit 1513 notifies the completion of the release. (FIG. 231) is returned to the telephone management server 1571 (step N62). The relay control unit 1513 sends a telephone call release notification to the relay switch 1518 (step N56), and the relay switch 1518 returns the completion of the release to the relay control unit 1513 (step N61). In addition, the relay switch 1518 sends a telephone call release notification to the switch 1519 (step N57), and the switch 1519 returns the completion of the release to the relay switch 1518 (step N60), and the switch 1519 A call cut-off signal is sent to the telephone 1520 (step N58).

<< End of media pass record >>

In step N55, the relay control unit 1513 instructs the audio control unit 1516 to erase the media path record of the media path connection table 1528-3 (FIG. 216) (step 1513-3 in FIG. 213), and the audio control unit 1513. 1516 reports record erasure of the media path (step 1516-3). The record can also be used for operational recording of the telephone call (connection / call / release) (optional).

<< Erase IP communication record and CIC control table record >>

The telephone management server 1571 sends the line number "CIC-2" written in the release IP packet 1565 to the table management server 1573 after step N55 (step N73), and the internal network node device 1544 The IP communication records " EA1, EA3, IA1, IA3 " corresponding to the line number "CIC-2" are erased (step N74). The record of the telephone set of the CIC management table 1571-2 (FIG. 205) managed by the telephone management server 1571 is erased. In addition, the telephone management server 1571 may use the record for the operation record of the telephone call (connection / call / release) (optional).

The relay control unit 1513 transmits the line number "CIC-2" written in the released IP packet 1566 to the table management server 1576 (step N71), and the IP communication record "EA3," in the network node device 1547. EA1, IA3, IA1 "are erased (step N72). In addition, the record of the telephone communication of the CIC management table 1513-3 (FIG. 222) managed by the relay control unit 1513 is erased. The record can also be used for operational records.

The above is summarized as follows.

The telephone access control IP communication line and the voice IP communication line are separated between the end gateway having the encapsulation function and the relay gateway, and the telephone 1, the end gateway and the relay gateway having the encapsulation function, the NNI interface communication line, the public switched telephone network, Telephone communication can be performed in two telephone periods via the telephone 2 in sequence. Further, both the telephone management server in the end gateway having the encapsulation function and the relay control unit in the relay gateway have individual CIC management tables, and the line numbers are managed using the individual CIC management tables. The relay control unit in the relay gateway converts the IP packet and the signal unit using an address connection table including address information in the IP packet and label information in the signal unit.

The relay control section searches the signal station address management table, presents the telephone number of the destination telephone, and acquires the signal station address of the exchange managing the telephone. In addition, the relay control unit determines the line number and signal link selection in accordance with the rules previously determined with the public switched telephone network.

The voice control unit converts the IP packet storing the digital voice and the voice signal transmitted inside the voice communication line of the NNI communication line using the media path connection table in the voice control unit in the relay gateway. Further, the IP packet and the signal unit are converted using an address connection table including address information inside the IP packet and label information in the signal unit. The voice control unit has an IP address for transmitting and receiving voice IP packets therein and is used for setting the media path connection table. The voice control unit also secures a logical voice communication line used for reception or transmission from the public switched telephone network and determines its identifier. An end gateway having an encapsulation function includes a relay control unit and a network node device. The network node device has functions of IP encapsulation and decapsulation. The relay control unit includes a telephone management server, a telephone number server, a surrogate telephone server, and a table management server. The telephone call control IP packet is transmitted to the relay control unit among the IP packets inputted from the media router to the network node device, and the voice IP packet is branched to the voice IP communication line. As such, the telephones 1508 and 1520 are capable of telephone communication via the IP transmission network 1500 and the public switched telephone network 1501.

14. Fourteenth embodiment using IP transmission as a relay network:

In FIG. 232, reference numeral 1400 denotes an IP transport network, reference numerals 1401 and 1402 denote a relay gateway, reference numeral 1403 denotes a gateway having an encapsulation function, reference numerals 1405 to 1407 denote a public switched telephone network (PSTN), and reference numerals 1408 to 1411 denote subscribers. Switch, reference numerals 1412 and 1413 are relay switches, reference numerals 1415 and 1416 are control communication lines to which the common line signaling method is applied, and reference numerals 1417 and 1418 are voice communication lines. In addition, the set of the control communication line 1415 and the voice communication line 1417 is an NNI communication line between the switch 1412 and the relay gateway 1401, and the set of the control communication line 1416 and the voice communication line 1418. Is the NNI communication line between the exchange 1413 and the relay gateway 1402. Reference numerals 1438 and 1439 denote an address connection table, reference numerals 1441 and 1442 denote gateway address management servers, and reference numerals 1443 and 1444 denote signal station address management servers. Reference numerals 1429 and 1430 denote media path connection tables. In the present invention, a point of a common line signal system is represented by a signal station and a point code is represented by a "signal station address".

The IP address of the relay gateway 1401 is "GW05" and the relay controller 1423 holds the IP address "GW05". Similarly, the IP address of the relay gateway 1402 is "GW06" and the relay controller 1424 is The IP address "GW06" is held.

<< Communication Between Telephone 1420 and Telephone 1421 >>

First, a method for controlling terminal-to-terminal communication connection from the telephone 1420 to the telephone 1422 via the public switched telephone network 1405, the IP transmission network 1400, and the public switched telephone network 1406 will be described.

<< connection phase >>

When the handset of the telephone 1420 is lifted, a call signal is transmitted to the switch 1408 (step HA01 in FIG. 233), the switch 1408 confirms the telephone call (step HA02), and the switch 1408 requests a telephone call setup. To the relay switch 1412 (step HA03). The relay exchange 1412 receives the call establishment request to form a signal unit 1451 of a common line signaling method, and passes the signal unit 1451 in the relay gateway 1401 via the control communication line 1415. It transfers to the relay control unit 1423 (step HA04). The destination signal station code of the signal unit 1451 is "DPC-1", the source signal station code is "OPC-1", the signal link selection is "SLS-1", the line number is "CIC-1", and the message is "IAM", the parameter is "Para-1" and the contents of the parameter "Para-1" include the telephone number "TN-1" of the telephone 1420 and the telephone number "TN-2" of the telephone 1421. do. The message "MSG-1" in the signal unit 1451 shown in FIG. 232 means "IAM".

<< operation of relay control unit 1423 >>

The relay control unit 1423 receives the signal unit 1451 (step HA04). 256 shows a procedure in which the relay control unit 1423 converts the signal unit 1451 to an IP packet. The relay control unit 1423 receives the signal unit 1451 (step S1461-2 in FIG. 256), and the signal station labels "DPC-1, OPC-1, SLS-1, and CIC-1 inside the signal unit 1451. &Quot; (step S1461-3), the signal station label, i.e., the destination signal station code (DPC), the source signal station code (OPC), the signal link selection (SLS), and the line number are stored in the address connection table 1438. It is checked whether or not a record containing the set of (CIC) exists (step S1461-4). In this case, since there is no matching record in the address connection table 1438-1 (FIG. 244), the signal station label is added to the record in the address connection table 1438 to be written (step S1461-5), and the relay control unit 1423 Withdraws the telephone number "TN-2" of the telephone 1421 in the parameter "Para-1", and the relay control unit 1423 queries the gateway address management server 1441 to manage the telephone number "TN-2". The IP address of the gateway to be answered is obtained (step S1461-6). In this case, the IP address "D-ad-x" of the relay gateway 1402 is obtained. Here, the gateway address management servers 1442 and 1442 input all ten digits of the telephone number or the upper six digits (long-distance station number and telephone station number), and output the IP address of the gateway managing the telephone number in question.

The gateway address management servers 1442 and 1442 can also be realized by a known technique of a domain name server (DNS) by replacing telephone numbers with domain names. When the number of telephone numbers to be queried is small, the IP address management table 1441-1 (FIG. 234) may be used instead of the gateway address management server. Here, the IP address management table 1441-1 summarizes the correspondence between the telephone number and the IP address of the relay gateway. When the telephone number is specified, the IP address of the corresponding relay gateway is obtained. In addition, the IP address management table is used for the same purpose as the IP transmission network output line table described in another embodiment, that is, to retrieve the correspondence between the telephone number and the IP address.

The relay control unit 1423 holds the IP address "S-ad-x" of the relay gateway 1401 to form an IP packet 1452. The destination IP address of the IP packet 1452 is "D-ad-x", the source IP address is "S-ad-x", the line number is "CIC-x", the message is "IAM", and the parameter "Para". -x "includes telephone number" TN-1 "of telephone 1420 and telephone number" TN-2 "of telephone 1421. The messages and parameters are obtained from the signal unit 1451, respectively (see FIG. 236). The relay control unit 1423 uses the line number "CIC-x" as a predetermined rule for each set of "S-ad-x" and "D-ad-x" (step S1461-7 in FIG. 256). For example, the value of the line number generated immediately before is stored in the internal memory, added and used one by one, and generated using the following calculation formula.

CIC-x = CIC-x + 1 mod 65536. (8)

The address connection table 1438 of the relay control unit 1423 is in a blank state before the relay control unit 1423 receives the signal unit 1451, and this state is shown as address connection table 1438-1 (FIG. 244). When the relay control unit 1423 forms the IP packet 1452, the label information " DPC-1, OPC-1, SLS-1, CIC-1 " in the signal unit 1451, and the inside of the IP packet 1452 are formed. Combining label information " S-ad-x, D-ad-x, CIC-x " and defining a media path identifier " MP-8 " It is added in the table (step S1461-8 in Fig. 256). This pattern is shown in address connection table 1438-2 (FIG. 245).

Of the signal station address items ("DPC-1, OPC-1") in the record of the address connection table 1438-2, the relay connection gateway 1401 on which the left "DPC-1" holds the address connection table 1438-2. Signal station address. Similarly, in the IP address items ("S-ad-x, D-ad-x") of the address connection table 1438-2, the relay connection gateway whose "S-ad-x" on the left holds the address connection table 1438-2. 1401 is an IP address. The right end of the record is the media path identifier "MP-8".

<< Linkage between relay control unit and voice control unit >>

A description with reference to FIG. The relay control unit 1423 presents the media path identifier " MP-8 " to the voice control unit 1427 via the information line 1429-1 (step 1423-1 in FIG. 251), and the voice control unit 1743 An internal IP address " IA5 ", an external IP address " EA5 " and a voice communication port number " 5010 " of the internal module of the voice control unit 1427 used for voice communication are secured, and the relay control unit ( 1423) (step 1427-1). In addition, the voice control unit 1423 determines a logical communication line identifier "CH-1" for identifying a logical communication line for transmitting the voice frame to the voice communication line 1417, and receives the voice frame from the voice communication line 1417. A logical communication line identifier "CH-2" identifying a logical communication line is determined, and the logical communication line identifiers "CH-1" and "CH-2" are written in a media path connection table 1429, and the result is a media path connection table. 1429-1 (FIG. 248).

In addition, when the logical communication line 1417 is a primary group speed interface line (PRI) of the ISDN communication line, the logical communication line identifier is a number indicating the device number of the ISDN communication device and a specific B channel (logical transmission line of user information). Consists of a set of.

The relay control unit 1423 is the IP address " GW05 "of the relay gateway 1401, the CIC number " CIC-2 " acquired or generated as described above, the telephone number " TN-1 " TN-2 ", IP addresses" EA5 "and" IA5 ", and port number" 5010 "are written in the CIC management table. The result is shown in CIC management table 1423-1 (FIG. 240). However, since order division is after step HA04, it is set as "IA". In addition, the relay control unit 1423 holds one or more internal IP addresses of the voice control unit 1743, and sets one of them as the internal IP address " IA5. &Quot;

<< Transmission in IP Transport Network >>

The relay control unit 1423 transmits the IP packet 1452 formed as described above (step S1461-9 in FIG. 256) to the IP transmission network 1400 (step S1461-10), and the IP packet 1452 is controlled by the communication. The relay control unit 1424 in the relay gateway 1402 is reached via the line 141-1, the router 1431, and the control communication line 1431-2 (step HA05).

<< relay control unit 1424: Setting of CIC management table and address connection table >>

The relay control unit 1424 receives the IP packet 1452 (step S1462-2 in Fig. 257). The IP address, message, line number, and parameters are retrieved from the IP packet 1452 (step S1462-3). Here, the destination IP address is "D-ad-x", the source IP address is "S-ad-x", the line number is "CIC-x", the message is "IAM", the parameter is "Para-x" , The parameter "Para-x" includes the telephone number "TN-1" of the telephone 1420 and the telephone number "TN-2" of the telephone 1421. In the address connection table 1439-1 (FIG. 246), it is checked whether there is a pair of corresponding IP addresses " S-ad-x ", " D-ad-x " and a line number (step S1462-4). In this case, since the pair does not exist, the IP addresses "S-ad-x" and "D-ad-x" and the line number address "CIC-x" are extracted and written in the address connection table 1439-1 ( Step S1462-5, the relay control unit 1424 presents the telephone number "TN-2" of the destination telephone to the signal station address management server 1444, and manages the telephone 1421 having the telephone number "TN-2". The signal station address "DPC-2" of the exchange 1409 is acquired (step S1462-6), and written in the address connection table 1439-1 of FIG. 246 (step S1462-7). As a result, the address connection table is 1439-2 (FIG. 247). The right end of the record is the media path identifier "MP-9".

The relay control unit 1424 determines the line number "CIC-2" and the signal link selection "SLS-2" according to the rules determined in advance with the public switching network 1406, and the message "IAM" and the parameter "Para-2". The signal unit 1453 to be included is formed (step S1462-8) and transmitted to the control communication line 1416 (step S1462-9).

<< Linkage between relay control unit and voice control unit >>

A description with reference to FIG. The relay control unit 1424 sends a media path identifier "MP-9" to the voice control unit 1428 via the information line 1430-1, an internal IP address "IA5" of the module in the voice control unit 1749, and an external device. When the IP address "EA5" and the port number "5010" used by the voice control unit 1427 for voice transmission are presented (step 1424-1 in FIG. 252), the voice control unit 1428 is configured to be internal to the module in the voice control unit 1428. The IP address " IA6 ", the external IP address " EA6 " and the port number " 5012 " used for voice transmission by the voice control unit 1428 are reported to the relay control unit 1424 (step 1428-1). In this order, the voice control unit 1428 is configured with two pairs of IP address and port number (external IP address "EA5" and port number "5010", internal IP address "IA6", external IP address "EA6" and port number "5012"). ) Is written in the media connection table 1430. The voice control unit 1428 also determines a logical communication line identifier "CH-3" for identifying a logical communication line for transmitting the voice frame to the voice communication line 1418, and receives the voice frame from the voice communication line 1418. The logical communication line identifiers "CH-4" for identifying the logical communication line to be specified are determined, and the logical communication line identifiers "CH-3" and "CH-4" are written in the media path connection table 1430. The result is shown in Media Path Connection Table 1430-1 (FIG. 249).

Media path connection table 1430-1 means receiving an IP packet (payload is UDP) having a source IP address "EA5", a source port number "5010", a destination IP address "EA6", and a destination port number "5012". In this case, the digitized voice is transmitted to the logical communication line identifier "CH-3" of the logical communication line 1418 by receiving the digitized voice from the logical communication line identifier "CH-4". Is stored in an IP packet (payload is UDP) having a source IP address "EA6", a source port number "5012", a destination IP address "EA5", and a destination port number "5010", and transmitted inside the IP transmission network 1400. It is.

In addition, a logical communication line for transmitting voice to the voice communication line 1418 is determined, and the logical communication line identifier "CH-2" is determined and written in the media path connection table 1430 together with the IP address and port number. The result of writing is as shown in Media Path Connection Table 1430-1 (FIG. 249).

<< Operation of Public Switched Telephone Network 1406 >>

Signal unit 1453 arrives at relay exchange 1413 (step HA06), and signal unit 1453 is transmitted from public switched telephone network 1406 to reach switch 1409 (step HA07). The exchange 1409 checks whether or not the telephone 1421 with the telephone number "TN-2" is allowed to receive, and if there is an incoming permission, notifies the telephone 1421 of the telephone call setting request (incoming notification) (step HA08). ).

Next, the exchange 1409 forms the signal unit 1454 shown in FIG. The destination signal station address in the signal unit 1454 is "DPC-3", the source signal station address is "OPC-3", the signal link selection is "SLS-3", and the line number is "CIC-3". Here, the value of "OPC-3" is the value of "DPC-2", the value of "DPC-3" is the value of "O PC-2", and the value of "SLS-3" is "SLS-2" Is a value of "CIC-3" and a value of "CIC-2". That is, the signal station address is a value obtained by exchanging the addresses of the source signal station and the destination signal station in the step, and the values of the signal link selection and the line number do not change.

Switch 1409 sends signal unit 1454 inside public switched telephone network 1406, and signal unit 1454 passes through switch 1413 (step HA11) and relays via control communication line 1416. The relay control unit 1424 inside the gateway 1402 is reached (step HA12).

The relay control unit 1424 receives the signal unit 1454 (S1461-2 in FIG. 256), draws out the signal station label inside the signal unit 1454 (S1461-3), and sets the signal station in the address connection table 1439. It is checked whether there are records with the same contents of the labels " DPC-3, OPC-3, SLS-3, CIC-3 " (step S1462-4). In this case, since there is a matching record in the address connection table 1439-2, an IP packet 1455 shown in FIG. 238 is formed next (S1461-9 in FIG. 256), and transmitted in the IP transmission network 1400 (S1461). -10). The source IP address in the IP packet 1455 is "S-ad-u", the destination IP address is "D-ad-u", and the line number is "CIC-u". Here, the value of "S-ad-u" is the value of "D-ad-x", the value of "D-ad-u" is the value of "S-ad-x", and the value of "CIC-u" The value is the value of "CIC-x". In other words, the address of the relay station gateway is a value obtained by exchanging a transmission source and a destination of the IP address of the IP packet 1452 in step HA05, and the value of the line number does not change. The IP packet 1455 reaches the relay control unit 1423 through the control communication line 1431-2, the router 1431, and the control communication line 1431-1 (step HA13 in FIG. 233). The relay control unit 1423 receives the IP packet 1455 (S1462-2 in FIG. 257), and IP addresses “S-ad-u” and “D-ad-u” and line number “from the IP packet 1455. CIC-u "is taken out. Then, inside the address connection table 1438, the label information "S-ad-u" matches "D-ad-x", the label information "D-ad-u" matches "S-ad-x" Since the line number "CIC-u" coincides with "CIC-x", the signal unit 1456 shown in FIG. 239 is formed (S1462-8 in FIG. 257). Next, it transmits to the control communication line 1415 (S1462-9), the signal unit 1456 reaches the relay switch 1412 (step HA14), and the signal unit 1456 is in the public switched telephone network 1405. It is sent to reach the exchange 1408 (step HA15).

On the other hand, the telephone 1421 receives the incoming notification by step HA08 and returns a signal unit indicating that the telephone call is being made to the exchange 1409 (step HA20), and the exchange 1409 signals the signal unit (CPG message) informing that the telephone is being called. ) Is notified to the exchange 1413 (step HA21). The exchange 1413 transmits the signal unit to the relay control unit 1424 of the relay gateway 1402 via the control communication line 1416 (step HA22), and the relay control unit 1424 has an address connection table 1439 therein. Referring to -2, an IP packet for notifying that the telephone call is in progress is formed by the same procedure as that shown in FIG. The formed IP packet passes through the control communication line 1431-2, the router 1431, and the control communication line 1431-1 to reach the relay control unit 1423 (step HA23).

The relay control unit 1423 forms a signal unit that receives the IP packet and notifies that the telephone call is in progress, and transmits the signal unit to the control communication line 1415 (S1462-9). The signal unit passes through the relay switch 1412 (step HA24) and reaches the switch 1408 (step HA25). Switch 1408 notifies phone 1420 that it is calling phone 1421 (step HA26).

Next, when the user of the telephone 1421 responds to the telephone call (step HA30), a signal unit for notifying the response is then sent from the exchange 1409 and passes through the exchange 1413 (step HA31), whereby the relay control unit ( 1424) (step HA32). The relay control unit 1424 refers to the address connection table 1439 to form an IP packet (ANM) for informing a response, and the IP packet includes a control communication line (1431-2), a router (1431), and a control communication line (1431-1). The relay control unit 1423 arrives via () (step HA33). In the relay control unit 1423, a signal unit for informing the response is formed by referring to the address connection table 1438, and passes through the switch 1412 (step HA34) and reaches the switch 1408 via the control communication line 1415 (step HA34). Step HA35). Switch 1408 sends a response signal to telephone 1420 (step HA36).

<< Completion of Address Connection Table >>

A description with reference to FIG. The relay control unit 1423 transmits the media path identifier "MP-8", the internal address "IA6", the external IP address "EA6" of the module in the acquired voice control unit 1428, and the voice control unit (1427). When 1428 presents the port number " 5012 " used for voice transmission (step 1423-2 in Fig. 253), the voice control unit 1427 sends the IP address " IA6, EA6 " to the media path connection table 1429-1 (Fig. 248). &Quot; and the port number &quot; 5012 are written, and the media path connection table 1429-2 (FIG. 250) is completed and reported to the relay control unit 1423 (step 1427-2).

In the connection phase, the line number "CIC-1" set by the public switched telephone network 1405 set for the telephone lines of the telephones 1420 and 1421, and the line number "CIC-x set by the IP transmission network 1400". Corresponds to the address connection table 1438, and the line number "CIC-x" set by the IP transport network 1400 and the line number "CIC-2" set by the public switched telephone network 1406 correspond to in the address connection table 1439. . These two correspondences are constant from the start to the end of telephony of the telephones 1420 and 1421.

<< Communication phase >>

In the above procedure, a call is enabled between the telephone 1420 and the telephone 1421, and voice communication is performed (step HA38). The voice sent from the telephone 1420 is divided into a telephone call connection control signal and a voice signal at the switch 1408, and then sent to the switch 1412, passing through the voice communication line 1417 and the voice control unit in the relay gateway 1401 ( Passing the voice communication line 1428 in the voice communication line 1433-1, the router 1433, the voice communication line 1433-2, the relay gateway 1402, and the voice communication line 1418 and the exchanger. 1413, the telephone 1441 is reached via the exchange 1409. Voice signals are transmitted from phone 1421 to phone 1420 in the reverse direction of the above description. A communication line of voice and dial-up control can be separated between the switch 1408 and the switch 1409.

<< liberation phase >>

When the user releases the handset, the release of communication from the telephone 1420 is notified to the switch 1408 (step HA40 in FIG. 233), and the switch 1408 notifies the switch 1412 of the release message REL (step). HA41). When the exchange 1412 receives the release message, it immediately returns the release completion message RLC to the exchange 1408 (step HA55), and the exchange 1412 notifies the relay control unit 1423 of the release message REL. (Step HA42). The relay control unit 1423 returns the release completion message RLC to the exchange 1412 (step HA54), and the relay control unit 1423 notifies the relay control unit 1424 of the release message REL (step HA43), The relay control unit 1424 returns the release completion message RLC to the relay control unit 1423 (step HA53). The relay control unit 1424 notifies the switch 1413 of the release message REL (step HA44), and the exchange 1413 returns the release completion message RLC to the relay control unit 1424 (step HA52). 1413 notifies the exchange 1409 of the release message REL (step HA45). The exchange 1409 returns the release completion message RLC to the exchange 1413 (step HA51), and the exchange 1409 informs the telephone 1421 of the release notification (step HA46).

In step HA42 (step S1463-2 in FIG. 258), the relay control unit 1423 determines that the signal unit is the release message REL (steps S1463-3, S1463-4, S1463-5), and the corresponding address table is used. The record to be erased is erased (step S1463-6). As a result, the record of the address connection table 1438-2 (FIG. 245) becomes blank as shown in the address connection table 1438-1 (FIG. 244). Similarly, in step HA43 (step S1464-2 in FIG. 259), the relay control unit 1424 determines that the message included in the signal unit is a release message REL (steps SI464-3, S1464-4, S1464-5). ), The corresponding record in the address connection table is erased (step S1464-6). As a result, the record of the address connection table 1439-2 (FIG. 247) becomes blank as shown in the address connection table 1439-1 (FIG. 246).

<< End of media pass record >>

In step HA43, the relay control unit 1423 instructs the audio control unit 1427 to erase the record of the media path "MP-8" in the media path connection table 1429-2 (FIG. 250) (step 1423 in FIG. 254). -3), the audio control unit 1423 reports the record erasure of the media path connection table (step 1427-3). In addition, the relay control unit 1424 instructs the audio control unit 1428 to erase the record of the media path " MP-9 " in the media path connection table 1430-1 (FIG. 249) in step N53 (Fig. 255). Step 1424-2), the audio control unit 1428 reports the record erasure of the media path connection table (step 1428-2). The record can also be used for operational recording.

<< Communication Between Telephone 1420 and Telephone 1422 >>

A method for controlling the communication connection between terminals that calls the telephone 1421 from the telephone 1422 via the media router 1404, the end gateway 1403 having an encapsulation function, the relay gateway 1402, and the public switched telephone network 1406. In other words, a method for controlling communication connection between terminals, such as telephone 1, media router, IP transmission network side, public switched telephone network, and telephone 2, has been described in another embodiment. The terminal 2-public telephone switching network-IP transmission network-media router-telephone 1-terminal communication connection control method which is the reverse of the above description can be performed by the order which can be easily inferred in substantially the same order. Inter-terminal communication from the telephone 1420 to the telephone 1422 via the public switched telephone network 1405, via the relay gateway 1401, the terminating gateway 1403 having an encapsulation function, and the media router 1404. In another embodiment, the access control method describes a function of a gateway having an encapsulation function, and can be implemented in substantially the same order as described above. In addition, the telephone unit 1420 passes through the public switched telephone network 1405, the relay gateway 1401, the terminating gateway 1403 having an encapsulation function, and the media router 1404, and the UNI communication line 1419 and the public. The terminal-to-terminal communication connection control method for calling the telephone 1423 via the telephone exchange network 1407 describes another terminal-to-terminal communication connection control procedure via a public switched telephone network via a UNI communication line. And can be carried out in approximately the same order.

The above is summarized as follows. In the end-to-end connection control between two telephones, telephone 1, public switched telephone network 1, NNI interface communication line 1, relay gateway 1 and relay gateway 2 belonging to the IP transport network, NNI interface communication line 2, public switched telephone network 2, telephone 2 Via the sequence. Alternatively, it is via the telephone 1, the public switched telephone network 1, the NNI interface communication line 1, the relay gateway belonging to the IP transport network, the gateway having the encapsulation function, the media router, and the telephone 2 in this order.

15. Example 15 without IP Encapsulation of Voice Line:

This embodiment is an example in which the network node device in the other embodiment is changed to an end device that is not IP encapsulated, the end gateway is changed to an unencapsulated end gateway, and the relay gateway is changed to an unencapsulated relay gateway. Voice IP packets do not encapsulate IP and exclude table management servers and alternate telephone servers.

In FIG. 260, reference numeral 1600 denotes an IP transmission network, reference numeral 1601 denotes a public switched telephone network, reference numeral 1602 denotes an unencapsulated termination gateway, reference numeral 1603 denotes an end device, reference numeral 1604 denotes an end gateway controller (SEP), and reference numeral 1605 An unencapsulated relay gateway, reference numeral 1606 denotes a relay control unit (STP), reference numeral 1607 denotes a voice controller, reference numeral 1608 a relay exchange, reference numeral 1609 a subscriber exchange, reference numeral 1610 a telephone with the telephone number "TN-1", Reference numeral 1611 denotes a telephone of telephone number "TN-2", reference numerals 1612 and 1613 denote control IP communication lines, reference numerals 1614 and 1615 denote voice IP communication lines, reference numeral 1616 denotes a control line of a common line signal system, and the like. Reference numeral 1617 denotes a voice communication line, reference numeral 1620 denotes an address management table, reference numeral 1671 denotes a telephone management server, and reference numeral 1672 denotes a telephone number server. The unencapsulated relay gateway 1605 is a relay gateway capable of mutual communication with the unencapsulated termination gateway 1602. An IP address capable of using devices external to the IP transport network such as the media router 1660 or a telephone is called an external IP address, and an IP transport network 1600 in which devices outside the IP transport network 1600 cannot be used. The internal dedicated IP address is called an internal IP address. The telephone management server 1671 has an external IP address " EA91 " and an internal IP address " IA91. &Quot;

<< connection phase >>

It is an example of telephone communication from telephone 1610 to telephone 1611. When the handset of the telephone 1610 is lifted, a call signal is transmitted to the media router 1660 (step B01 in FIG. 261), and the media router 1660 confirms the telephone call (step B02). Next, the source IP address "EA1", the destination IP address "EA91", the telephone number "TN-1", the telephone number "TN-2", the port number "5006" for voice transmission, and the additional information "Info-2". IP packet 1630 (FIG. 262) including the above is formed and transmitted to the end device 1603 (step B03). Here, IP address "EA1" is the IP address of the media router 1660, IP address "EA91" is the external IP address of the telephone management server 1671, the payload portion of the IP packet 1630 is a UDP packet, and the source and This is an example where all destination port numbers are "5060".

<< Packet Filter by Terminator >>

When the terminating device 1603 receives the IP packet 1630, the terminating device 1603 includes a source IP address "EA1", a source port number "5060", a destination IP address "EA91", and a destination port number included in the IP packet 1630. It is checked whether all of " 5060 " are registered as records in the address management table 1620. In this case, since it is included as the first row record of the address management table 1620-1 (FIG. 263), the terminator 1603 stores the destination IP address " EA91 " in the IP packet 1630 inside the telephone management server. Convert to IP address "IA91" (NAT function). Next, according to the designation of the output interface "IF1612" at the right end of the record in the address management table 1620-1, the control IP communication line 1612 is sent as an IP packet 1631 (step B04). In the case where the IP address and port number in the received IP packet 1630 are not registered in the address management table 1620, the IP packet 1630 is discarded. In this way, the IP packet is filtered.

<< Formation of CIC Management Chart >>

The telephone management server 1671 receives the IP packet 1631, and records the internal IP address " IA91 " of the telephone management server 1671, the order classification " IAM, in a record of the CIC management table held by the telephone management server 1671. ", Source telephone number" TN-1 ", destination telephone number" TN-2 "," EA1 "of the IP address, the port number" 5006 "for voice transmission, and" St6 "for writing time (date, month, date, time, seconds). It fills in as CIC management table 1671-1 (FIG. 264).

Next, the telephone management server 1671 shows the IP number 1632-1 (FIG. 265) asking the destination telephone number "TN-2" to the telephone number server 1672 (step B06), and the telephone number server 1672. ) Stores the IP address " GW03 " in IP packet 1632-2 (FIG. 266) and responds (step B07). The IP address "GW03" is an IP address of the relay gateway 1605.

<< Management of line number >>

The telephone management server 1671 determines the CIC number "CIC-2" according to the CIC number formation rules defined for the set of the IP address "IA91" and the IP address "GW03", and together with the IP address "GW03" in the CIC management table. Fill in. The result is recorded in the record of CIC management table 1671-2 (FIG. 267). Next, the telephone management server 1671 forms an IP packet 1634 (see FIG. 268, IAM packet) with reference to the IP packet 1163 and the CIC management table 1671-2, and converts the IP packet 1634 into a relay gateway ( 1605) (Step B09).

<< Operation of Relay Control Unit >>

When the relay control unit 1606 receives the IP packet 1634 (FIG. 268) (step B09), the IP address 1IA, the destination IP address "IA91", the destination IP address "GW03", and the line number "CIC-2" from the IP packet 1634. ", Sequence division" IAM ", source telephone number" TN-1 ", destination telephone number" TN-2 "," EA1 "of the external IP address, and port number" 5006 "for voice transmission, and the relay gateway ( 1605) is a record of CIC management table 1605-1 (FIG. 269) held therein, and is recorded with the time " St7 &quot;.

The relay control unit 1606 also retrieves the signal station address management table 1627 (FIG. 270), presents the telephone number " TN-2 ", and manages the signal station address " PC-09 " Get. In addition, the relay control unit 1606 determines the signal link selection "SLS-3" and the line number "CIC-3" in accordance with the rules determined in advance with the public switched telephone network 1601. The relay control unit 1606 sets the signal station address "PC-3" of the relay gateway 1605, the "PC-09" obtained, the signal link selection "SLS-3", the line number "CIC-3", and the IP. The address " GW03 ", the IP address " IA91 " and the line number " CIC-2 " are written as a new record of the address connection table 1625 together with the media path identifier " MP-7 ". As a result, the address connection table is as shown in 1625-1 (FIG. 271). Subsequently, the relay control unit 1606 carries out the signal station addresses "PC-09" and "PC-3", the signal link selection "SLS-3" and the line number "CIC-3", the message "IAM", and the telephone number. A signal unit 1635 including "TN-1" and "TN-2" is formed (FIG. 272), and transmitted to the control communication line 1616 (step B10).

<< Linkage between relay control unit and voice control unit >>

The relay control unit 1606 notifies the voice control unit 1607 of the media path identifier "MP-7", the external IP address "EA1", and the port number "5006" for voice transmission via the information line 1629. The voice control unit 1607 writes the informed information as a record of the media path connection table 1628. The voice control unit 1607 also determines a logical communication line for transmitting voice from the voice control unit 1607 to the voice communication line 1617, and records the logical communication line identifier "CH-1" in the media path connection table 1628. Write as. The above results are shown in Media Path Connection Table 1628-1 (FIG. 273).

<< Switch Network Behavior and ACM Messages >>

The exchange 1608 receives the signal unit 1635 via the control communication line 1616 (step B10), and transmits the signal unit 1635 to the exchange 1609 (step B11). The exchange 1609 receives the signal unit 1635, checks whether the destination telephone number " TN-2 " contained therein can be received, and notifies the telephone 1611 of an incoming call if the call is possible (step). B12). Further, a signal unit 1635-1 (FIG. 275) which informs reception of the signal unit 1635 is formed and returned, and the signal unit reaches the relay gateway 1605 via the switch 1608 (step B13). (Step B14). The relay control unit 1606 obtains address information for forming an IP packet with reference to the address connection table 1625-1 (FIG. 271) based on the received label information of the signal unit 1635-1. IP packet 1651 (ACM message, see FIG. 276) is formed, and IP packet 1651 is transmitted to telephone management server 1701 (step B15). The telephone management server 1671 fetches the line number "CIC-2" and the sequence division "ACM" from the received IP packet 1651, and the CIC management table 1671-2 (FIG. 267) held by the telephone management server 1671 (FIG. 267). To find the record having its own IP address " IA91 ", the relative IP address " GW03 " and the line number " CIC-2 ", and rewrite the order division column of the corresponding record of the CIC management table 1671-2 to the " ACM ". do.

Next, the telephone management server 1671 forms an IP packet indicating that the ACM message has been received, and notifies the media router 1660 (steps B18 and B19).

<< Media Pass Connection Table >>

In parallel with the above step B10 or after completing step B10, the relay control unit 1606 presents the media path identifier " MP-7 " to the voice control unit 1607, and simultaneously requests an IP address and a port number. In this way, the voice control unit 1607 transmits the IP address "EA7" of the IP packet transmitted by the voice control unit 1607 to the voice IP communication line 1615 and the port number "5008" of the UDP packet to the relay control unit 1606. Reply The voice control unit 1607 also secures the logical voice communication line received from the exchange 1608, and records the identifier " CH-2 " in the record of the media path connection table 1628-2 (FIG. 274). The left side of the record of the media path connection table is arranged such that the voice control unit 1607 has the IP address "EA7" and the port number "5008", and the right side has the IP address "EA1" and the port number "5006" of the communication counterpart. . The relay control unit 1606 receives the IP address "EA7" and the port number "5008" and writes it to the CIC management table 1605-1 (FIG. 269). The result is the same as CIC management table 1605-2 (FIG. 279).

<< Sending CPG Messages >>

When the telephone 1611 reports to the switch 1609 that the telephone is being called (step B20), the switch 1609 forms and transmits a signal unit (CPG message) indicating that the telephone is being called, and the signal unit 1608 ), The relay gateway 1605 is reached (step B22). Based on the received label information of the signal unit, the relay control unit 1606 obtains address information for forming an IP packet with reference to address connection table 1625-1 (FIG. 271), and CPG message 1652 (FIG. 277). The IP packet is sent to the telephone management server 1671 (step B23), and the telephone management server 1671 notifies the telephone 1610 via the media router 1660 that the telephone call is in progress (steps B26 to I). B28). When forming the CPG message, the relay control unit 1606 obtains the external IP address "EA7" and the port number "5008" from the CIC management table 1605-2 (FIG. 279) and writes them in the CPG message 1652. The telephone management server 1671 can extract the external IP address "EA7" and the port number "5008" from the received CPG packet 1652 and write it to the management table 1671-2 (FIG. 267).

<< Sending ANM Message >>

Next, when the user of the telephone 1611 answers the telephone call (step B30), the exchange 1609 forms and transmits a signal unit (ANM message) informing the response, and the signal unit passes through the exchange 1608. (Step B31), the relay control unit 1606 is reached (step B32). The relay control unit 1606 forms an ANM message 1653 (FIG. 278) in the form of an IP packet with reference to address connection table 1625-1 (FIG. 271) on the basis of the received label information of the signal unit. 1653 is transmitted to the telephone management server 1671 (step B33). The telephone management server 1671 notifies the telephone 1610 of the response notification via the media router 1660 (steps B36 to B38). That is, the IP packet 1656 (FIG. 282) is sent from the telephone management server 1701 to the media router 1660 via the terminator 1603 (step B36) (step B37).

When forming the ANM message, the relay control unit 1606 obtains the external IP address "EA3" and the port number "5008" from the CIC management table 1605-2 (FIG. 279), and writes them in the ANM message 1653. The telephone management server 1671 can retrieve the external IP address " EA7 " and the port number " 5008 " from the received response packet 1653 and write it to the CIC management table 1671-2 (FIG. 267).

<< write timing to CIC management table >>

The telephone management server 1671 fetches the external IP address "EA7" and the port number "5008", fills it in the CIC management table 1671-2, and forms the CIC management table 1671-3 (FIG. 280) in the above description. Only either step B23 having received the CPG message or step B33 having received the ANM message.

<< Write to Address Management Table >>

The telephone management server 1671 uses the external IP address " EA1 " of the media router 1660 to which the source telephone 1610 is connected from the CIC management table 1671-3 (FIG. 280), and the port that the media router 1660 uses for voice transmission. The terminal 1603 together with the number " 5006 ", the external IP address " EA7 " inside the voice controller 1607, and the port number " 5008 " used by the voice controller for voice transmission, and the voice transmission interface " IF1614 " Is written in the address management table 1620 (step B39). The result is shown in the records " EA1, 5006, EA7, 5008, IF1614 " in the third row of the address management table 1620-2 (FIG. 281).

<< Communication phase >>

The telephone communication between the user of the telephone 1610 and the telephone 1611 is made in the same steps as described in the other embodiments. The analog voice of the telephone 1610 is digitized and carried in the payload of the IP packet 1601 (FIG. 283). The source address of the IP packet 1601 is the IP address "EA1" of the media router 1660, the destination address is the IP address "EA7" inside the obtained voice control unit 1607, and the voice transmission port number of the media router is "5006." "The UDP port number used by the voice control unit 1607 for voice transmission is" 5008 ".

Since the IP address and port number in the IP packet 1601 are included in the third record "EA1, 5006, EA7, 5008, IF1614" of the address management table 1620-2, the IP packet 1601 is the output line interface ". IF1614 "is sent to the voice IP communication line 1614 as an IP packet 1662, and passes through the router 1624 and the voice IP communication line 1615 to reach the voice control unit 1607 of the relay gateway 1606. do.

The voice control unit 1607 extracts the IP address and port number "EA1, 5006, EA7, 5008" from the received IP packet 1662, and the IP address and port number in the media path connection table 1628-2 (FIG. 274). Searches for matching records. Here, since the set of the IP address and the port number included in the first row record of the media path connection table match, the IP packet 1662 is regarded as a normal IP packet and received. In the case of mismatch, the IP packet is discarded.

Next, the digitized voice in the IP packet 1662 is converted into a voice frame 1664 (FIG. 284) in the form of being transmitted on the voice communication line 1617, and the voice frame 1664 is exchanged via the switch 1608. 1609, voice is output from the telephone 1611. The voice stored in the voice frame sent from the phone 1611 is sent in the opposite direction to the phone 1610.

<< liberation phase >>

When the user of the telephone 1610 notifies release of telephone communication (step B50 of FIG. 261), the media router 1660 sends a telephone call release notification to the telephone management server 1701 (steps B51 to N52), and telephone management. The server 1671 returns the completion of the release to the media router 1660 (steps B64 to B66). The telephone management server 1671 sends an IP packet 1665 (FIG. 285) informing the release of the telephone call to the relay control unit 1606 (step B55), and the relay control unit 1606 sends the IP packet 1666 informing the completion of the release. 1671 (step B62), the relay control unit 1606 sends a telephone call release notification to the relay switch 1608 (step B56). The relay switch 1608 returns the completion of the release to the relay control unit 1606 (step B61), and the relay switch 1608 sends a telephone call release notification to the switch 1609 (step B57), and the switch 1609 releases the switch. The completion is returned to the relay switch 1608 (step B60), and the switch 1609 sends a telephone call disconnection signal to the telephone 1611 (step B58).

<< End of media pass record >>

In step B55, the relay control unit 1606 instructs the voice control unit 1607 to erase the record of the corresponding media path set according to the media path connection table 1628-2 (FIG. 274), and the CIC management table 1605-2 (FIG. 279). ) Indicates the end of the record. In addition, the corresponding record of the address connection table 1625-1 (FIG. 271) set by the said telephony connection control is erased.

<< Erase Address Management Table and CIC Management Table Records >>

The telephone management server 1671 erases the corresponding record of the CIC management table 1671-3 (FIG. 280) set by the telephony connection control, and at the same time the address management table 1620-2 (FIG. 281) managed by the terminating device 1603. Instructing end device 1603 to erase the record (step B69).

<< Variant of Termination >>

The terminator 1603 may not perform the function of changing the address inside the accepted IP packet (NAT function). In this case, the external IP address "EA91" of the telephone management server and the internal IP address "IA91" match.

<< other variations of terminations >>

The IP address may not be included in the address management table 1620 in the terminator 1603, and is shown as the address management table 1620-3 (FIG. 287). In this case, the IP address is not registered, but the port number "5060" is used for the terminal-to-telephone connection control, the port number "5004" to "5048" is used for voice communication of the telephone, and the IP of another port number is used. Discard the packet. In this way, transmission and reception of IP packets other than the telephone is prohibited.

As such, the telephones 1610 and 1611 are capable of telephone communication via the IP transmission network 1600 and the public switched telephone network 1601. The relay gateway includes a relay control unit and a voice control unit, and the relay control unit includes a connection correspondence table and a signal station address management table. The voice control unit includes a media path connection table. The voice control unit determines the logical communication channel in the voice communication line 1617, and writes the channel identifier "CH-j" into the media path connection table. IP packet filtering is performed using only the unencapsulated end gateway and the unencapsulated relay gateway to pass only the IP packets registered with the set of IP addresses and port numbers by the address management table of the end device inside the unencapsulated end gateway. Alternatively, IP packet filtering may be performed such that only IP packets registered with a port number are passed through the address management table. In addition, telephone communication can be performed between a telephone connected to a public switched telephone network and a telephone connected to an IP transmission network.

16. Embodiment 16 in which a control line and a voice line are separated and connected to a public switched telephone network.

In FIG. 288, reference numerals 1700 and 1701 denote an IP transmission network, reference numeral 1702 denotes a public switched telephone network (PSTN), reference numerals 1703 and 1704 denote an end gateway having an encapsulation function, and reference numeral 1705 denotes a control line 1738 of a common line signaling method. Relay gateway to be connected, reference numerals 1706 and 1707 denote relay gateways connected to an IP communication line, reference numerals 1710 to 1713 and 1718 denote relay control units, reference numerals 1714 and 1715 denote network node devices, reference numerals 1716 and 1717 denote voice control units, Reference numerals 1720 and 1721 denote telephones, reference numerals 1725 to 1729 denote control communication lines, and reference numerals 1731 to 1736 denote voice communication lines. Reference numerals 1725 to 1736 are also IP communication lines. Reference numeral 1738 denotes a control communication line of a common line signal system, and reference numeral 1739 denotes a voice communication line. Network node devices 1714 and 1715 have IP encapsulation and are described in other embodiments. The IP transport networks 1700 and 1701 are separate IP transport networks in that they are operated by other carriers, but IP packets can be transmitted from one side to the other via either of the communication lines 1725 and 1734.

The relay control unit 1710 in the end gateway 1703 having the encapsulation function includes a telephone management server, an alternate telephone server, a telephone number server, and a table management server as described in another embodiment, and likewise, the relay control unit 1713. Also includes a telephone management server, a surrogate telephone server, a telephone number server, and a ticket management server.

<< connection phase >>

It is an example of carrying out telephone communication from the telephone 1720 to the telephone 1721. In FIG. 289, reference numeral 1700-1 denotes the range of the IP transmission network 1700, and reference numeral 1701-1 denotes the range of the IP transmission network 1701, respectively. When the handset of the telephone 1720 is lifted, a call signal is transmitted to the media router 1722 (step E01), and the media router 1722 confirms the telephone call (step E02). Next, the media router 1722 sends a telephone call connection request IP packet including the telephone number "TN-1" of the telephone 1720 as the source and the telephone number "TN-2" of the telephone 1721 as the destination. Form and transmit to network node device 1714. The network node device 1714 inputs the IP packet, applies an IP encapsulation described in another embodiment, forms an internal IP packet, and relays the control unit within an end gateway 1703 having the function of encapsulating the IP packet. 1710) (step E03).

The network node device 1714 returns the reply IP packet to the media router 1722 in step E03 (step E04), forms an IP packet 1750 of the telephone call connection request, and sends it to the control IP communication line 1725. In this way, the IP packet 1750 reaches the relay control unit 1711 via the control IP communication line 1726 (step E05). IP packet 1750 includes source IP address "S-ad-4", destination IP address "D-ad-4", line number "CIC-4", message "IAM", and parameter "Para-4". do. The parameter includes telephone numbers "TN-1" and "TN-2". The destination IP address "D-ad-4" has a first case which is an IP address of the relay control unit 1713 and a second case which is an IP address of the relay control unit 1712. In the first case, the IP packet 1750 arrives at the relay control unit 1712 in the relay gateway 1712 via the control communication line 1727 as it is (step E06).

In addition, relay control units 1711 and 1712 store IP addresses "S-ad-4", "D-ad-4", line number "CIC-4", IAM, and telephone number "TN" in IP packet 1750. -1 "," TN-2 ", and the like can be recorded as the CIC management table 1711-1 (FIG. 290) as described in the other embodiments. The relay control unit 1712 is as described in the other embodiments. In the second case, when the relay control unit 1712 receives an IP packet, the IP number of the IP packet 1750 from the destination telephone number "TN-2" is received using the telephone number server. The new destination IP address in the transmission network 1701 is retrieved and used as the destination IP address of the IP packet 1750. The IP packet 1701 sent by the relay control unit 1712 is the same as the IP packet 1750, or The packet sets the above-mentioned new IP address.

The IP packet 1751 reaches the relay control unit 1713 of the termination gateway 1704 having the packet function via the control communication lines 1728 and 1729 (step E07). In addition, the relay control unit 1713 is described in another embodiment and includes a telephone management server, a substitute telephone server, a telephone number server, and a table management server. The telephone management server in the relay control unit 1713 sends an IP packet informing the media router of the telephone call request based on the IP packet 1751, and the media router 1723 receives the IP packet (step E08).

The media router 1723 notifies the telephone 1721 of the telephone call setting request (step E09), and returns an IP packet informing that it has received step E08 (step E11). The relay control unit 1713 forms an ACM packet and returns it (step E12), and the ACM packet passes through the relay control units 1712 and 1711 to reach the relay control unit 1710 (steps E13 and E14). If the media router is notified that the telephone 1721 is being called (step E20), the media router 1723, the relay control units 1713, 1712, 1711, 1710, and the media router 1722 are called to the telephone 1720. It is known that the call is in progress (steps E21 to E26). When the phone 1721 responds, the phone 1721 is known to the phone 1720 through the media router 1723, the relay controllers 1713, 1712, 1711, 1710, and the media router 1722, so that the call can be made. (Steps E30 to E36).

Voice communication is performed between the telephone 1720 and the telephone 1721 (step E38). The voice sent from the telephone 1720 is digitized by the media router 1722 and stored in an IP packet, and the network node device 1714, communication lines 1731, 1732, 1733, voice control unit 1716, and communication line 1734. The media router 1723 is reached via the voice control unit 1725, the communication lines 1735 and 1736, and the network node device 1715, where the digitized voice becomes analog voice and reaches the telephone 1721. . The IP encapsulation and decapsulation of IP packets in network node devices 1714 and 1715 is described in another embodiment. When the telephone 1720 generates a release request (step E40), as described in the other embodiments, a series of telephone call release and release completion procedures are completed and communication is completed (steps E41 to E45, steps 51 to 51). E55).

<< Connection of various networks >>

FIG. 291 shows a diagram of a public switched telephone network and an IP transport network connection, together with other embodiments. Reference numerals 1760 and 1761 denote the public switched telephone network (PSTN), reference numerals 1762 and 1763 denote the IP transport network, reference numerals 1764 and 1765 denote the subscriber exchange (LS), reference numerals 1766 and 1767 the relay exchange, and reference numerals 1768 to 1771 encapsulate. End gateways having functions, reference numerals 1772 and 1773 are relay gateways, reference numerals 1776 to 1779 are media routers, and reference numerals 1780 to 1785 are telephones. Each switch includes a relay control unit and a voice control unit, and an end gateway and a relay gateway having an encapsulation function also include a relay control unit and a voice control unit. The switch and the gateway are connected by a control communication line and a voice control line. A network node device is installed between the control gateway between the relay gateway 1772 and the end gateways 1768 and 1769 having an encapsulation function, and the control between the relay gateway 1773 and the end gateways 1770 and 1771 having an encapsulation function. Install network node devices between lines. Since this is described in another embodiment, it is omitted in FIG.

Thus, for example, the telephones 1178 and 1785 are the media router 1776, the end gateway 1768 with encapsulation, the relay gateway 1772, the relay gateway 1773, and the end gateway with encapsulation ( 1771) Telephone communication is possible by the terminal-to-terminal communication connection control via the media router 1779. FIG.

In addition, between the telephone 1780 and the telephone 1785, the switch 1764, the switch 1668, the relay gateway 1772, the relay gateway 1773, the termination gateway 1671 having the encapsulation function, and the media router 1779 Telephone communication is possible by the terminal-to-terminal communication connection control via. In addition, communication between terminals is performed between the telephone 1780 and the telephone 1781 via the exchange 1764, the exchange 1668, the relay gateway 1772, the relay gateway 1773, the exchange 1767, and the exchange 1765. Telephone communication is possible by connection control. However, this case is effective for cases in which the exchangers 1766 and 1767 are geographically far apart.

<< Example using an unencapsulated end gateway >>

As described above, the various networks are connected, and as shown in Fig. 292, the non-encapsulated end gateways 1768x to 1771x are used without using the end gateways 1768 to 1771 having the encapsulation function. Unencapsulated relay gateways 1772x and 1773x that can communicate with end gateways having an unencapsulation function without using relay gateways 1772 and 1773 are used.

As described above, telephony communication is performed by the same terminal-to-terminal communication connection control between the telephone 1762 and the telephone 1785, between the telephone 1780 and the telephone 1785, and between the telephone 1780 and the telephone 1781. This is possible. In this way, through the end gateway and the relay gateway having the encapsulation function belonging to the telephone 1, the media router 1, and the IP transport network 1, and the end gateway having the encapsulation function different from the other relay gateways belonging to the IP transport network 2, The telephone communication can be performed in two telephone periods via the media router 2 and the telephone 2. In addition, through the non-encapsulated function gateway and the non-encapsulated function relay gateway belonging to the telephone 1, the media router 1, and the IP transport network 1, and the end gateway having an encapsulation function different from other relay gateways belonging to the IP transport network 2, Telephone communication can be performed in two telephone periods via router 2 and telephone 2 in sequence.

In the case where the IP packet which receives the relay control unit 1712 of the IP transmission network 1701 from the IP transmission network 1700 operated by the communication company X to the IP transmission network 1701 operated by the communication company Y is input, When the control unit 1712 receives the IP packet, the control unit 17 inquires a telephone number server, and the IP of another relay control unit 1713 of the IP transmission network involved in connection to the destination telephone number "TN-2" included in the IP packet. An IP packet obtained by acquiring an address and newly setting the acquired IP address is transmitted to the other relay control unit 1713.

17. Seventeenth embodiment for performing multicast communication:

This embodiment will be described with reference to FIGS. 293 to 295. Network node devices 1801 to 1805 and routers 1807 to 1809 are installed in the IP transport network 1800. The network node device and the router are connected directly or indirectly via the network node device or the router by an IP communication line. Terminals 1810-1 to 1810-19 having an IP packet transmission / reception function are connected to a network node device via an IP communication line. Reference numerals 1811-1 to 1815-1 denote address management tables of network node devices, and reference numerals 1817-1 to 1819-1 denote route tables of routers.

Reference numeral 1868 in FIG. 294 denotes a main location of a server class that realizes a terminal-to-terminal communication connection control function in multicast communication, reference numeral 1857 denotes a multicast management server, reference numerals 1855 and 1856, refer to a user service server. 1853 and 1854 are acceptors, 1851 are multicast service providers, 1852 are multicast service purchasers, 1850 are routers, 1859 are tree building servers, 1858 are resources of the IP transport network 1800 Management server, 1861-1863, is a table management server. Reference numerals 1841 to 1845 denote overflow communication lines through which unscheduled IP packets are output when a multicast record is set. The server or router in the IP transmission network 1800 is given an IP address and has an IP communication means capable of exchanging information with each other by transmitting and receiving IP packets. In addition, in the present embodiment, the terminal or the server may give a plurality of multicast IP addresses in addition to having unique IP addresses.

The terminal 1810-2 is also a transmitting terminal for transmitting multicast data in a multicast service. Multicast data includes so-called multimedia data such as digitized voice and fax data, still images and moving pictures.

<< communication record >>

The row of the address management table is called a communication record or IP communication record. For example, the second "I01, E01, E26, I26, G03, F02" in the address management table 1811-1 is used as the communication record between the external IP address "E01" and the external IP address "E26", or the external IP address "E01". A communication record for determining an IP communication path between a terminal 1810-2 having a terminal and a terminal 1810-16 having an external IP address "E26". When the contents of the communication record are "a, b, c, d, e, f", the first item is "a" and the second item is "b", which is the same below. When the item is an address, for example, the third address item is called "c".

Sender internal IP address, which assigns the first item of the communication record to the logical terminal of the sending side (the logical contact between the external IP communication line and the network node device), the second item is the source external IP address, and the third item is the destination external IP address. The fourth item is designated as the destination IP address of the destination, the fifth item is designated as the destination of the internal IP packet, and the sixth item is designated as the destination of the external IP packet.

<< IP transmission between two terminals >>

The external IP dress "E01" is given to the terminal 1810-2 of FIG. 293, the internal IP address "I01" is given to the end of the network node device 1801 side of the communication line 1822, and the terminal (FIG. The external IP address "E26" is given to 1810-16, and the internal IP address "I26" is given to the end of the network node device 1804 side of the communication line 1826-6. The internal numerical values of the address management tables 1811-1 to 1815-1 of the network node apparatus indicate a state in which initial values are set by the same method as described in the other embodiments, and will be described below by IP packet transmission.

The terminal 1810-2 sends an external IP packet 1829-1 having a source external IP address "E01" and a destination external IP address "E26" to the communication line 1822, and the network node device 1801 is external. Receive the IP packet 1829-1. Next, the network node device 1801 displays three IP addresses obtained by the second record "I01, E01, E26, I26, G03, F02" of the address management table 1811-1, that is, the communication line 1810-2. The internal IP address " I01 " given to the end of " ", the sender external IP address " E01 " in the received external IP packet 1829-1, and the destination external IP address " E26 " Internal IP packets are formed using " I01 and I26 " included in the record, and are sent as internal IP packets 1829-2 to the communication line 1823-2 designated by " G03 " In the order of the above IP encapsulation, since the internal packet output designation "G03" (fifth item) of the communication record "I01, E01, E26, I26, G03, F02" is other than "0", the IP is encapsulated and the internal IP. A packet is formed and outputted. When the internal packet output designation is "0", the IP packet is transmitted to the overflow communication line 1841 of the network node device without encapsulation.

The router 1809 receives the internal IP packet 1829-2, and sends the internal IP packet 1829-2 to the communication line 1824-2 designated by the output interface "G21" designated by the route table 1819-1. Send the copied internal IP packet (1829-3). The network node device 1804 receives the internal IP packet 1829-3, and the record " I26, E26, E01, I01, G36, F16 " in the third row of the address management table 1814-1 indicates the internal IP packet 1829-3. 3) confirm that the IP addresses " I26, E01, I01 " are included, and restore the external IP packet by decapsulation excluding the IP header of the internal IP packet 1829-3. It transmits as an external IP packet 1829-4 to the communication line 1826-6 designated by the output interface " F16 " The terminal 1810-16 receives the external IP packet 1829-4.

<< type of terminal >>

The terminals 1810-1 to 1810-19 are data terminals having a data transmitting / receiving function, a telephone having a function of transmitting / receiving digitized voice, a voice transmitting terminal capable of transmitting digitized voice (ie, a wired voice broadcasting transmitter), and a digitized voice. A voice receiving terminal capable of receiving audio signals (i.e., a receiver for wired voice broadcasting), a voice video transmitting / receiving terminal having a function of transmitting and receiving digitized voice and images, or a TV conference terminal, and a voice image transmitting terminal capable of transmitting digitized voice and moving images (i.e. , A wired voice image transmitter), a voice image receiving terminal capable of receiving digitized voice and moving pictures (ie, a wired TV receiver), and the terminal is a data terminal connected to the media router and the media router described in another embodiment. Or any combination of a telephone and an audio visual apparatus. Since the transmission data or the reception data from any of the terminals are stored in the payload portion of the IP packet, the multicast technique described below can be applied to all terminals.

<<Preparation for conducting multicast communication >>

The terminal 1810-2 is a multicast transmitting terminal, and the terminals 1810-11, 1810-13, 1810-14, 1810-17, and 1810-18 are multicast receiving terminals. A method for controlling communication between terminals is described.

296 shows the cost of a communication line connecting between a network node device and a router in the IP transmission network 1800 as a positive integer for each communication line, and communication between the network node device 1801 and the router 1807. The cost is "1", the communication cost between the network node device 1801 and the router 1809 is "2", the communication cost between the network node device 1802 and the router 1807 is "2", and the network node device ( The communication cost between the 1802 and the router 1809 is "1", the communication cost between the router 1807 and the router 1808 is "1", and the communication cost between the router 1807 and the router 1809 is "3". ", The communication cost between the router 1808 and the router 1809 is" 3 ", the communication cost between the router 1808 and the network node device 1803 is" 1 ", the router 1808 and the network node device 1804 Communication cost between the router 1809 and the network node device 1804 is " 1 ", and the communication cost between the router 1809 and the network node device 1805 is " 1 " Indicate that And there.

The IP transport network 1800 includes other routers and communication lines in addition to those shown in FIG. 296, but shows only routers and network node devices involved in calculating communication costs. In addition, although the communication cost of a transmission line is "2" and the reception line communication cost is "3" etc., what is necessary is just to differ according to a transmission direction and a reception direction, but in this embodiment, the communication cost of a transmission line and a reception line is set to the same value. Doing.

The network resource management server 1858 of FIG. 294 holds functions of various resources such as routers, servers, and communication lines in the IP transmission network 1800 in its internal database. 297 is a cost table 1869 showing the communication cost of the communication line between the network node device and the router held by the network resource management server 1858. The symbol "N1801" in the cost table 1869 represents the network node device 1801, and the symbol "R1807" represents the router 1807. The cost table 1869 shows the communication line costs shown in FIG. 296 in the form of a table. For example, "1" in the second row and the seventh column of the cost table 1869 indicates the communication cost from the network node device 1801 to the router 1807. Indicates that this is "1", and "2" in the second row and ninth column of the cost table 1869 indicates that the communication cost from the network node device 1801 to the router 1809 is "2". "2" in the third row and the seventh column indicates that the communication cost from the network node device 1802 to the router 1807 is "2", and "1" in the third row and the ninth column of the cost table 1869 indicates the network node device. The communication cost from the 1802 to the router 1809 is " 1 ", which is the same as below.

Next, a procedure for multicast communication will be described with reference to FIGS. 298 to 300. The sender 1801 (FIG. 294) such as multicast data requests the acceptor 1853 to connect the terminal 1810-2 to the network node device 1801 as a transmitting terminal such as multicast data (step of FIG. 300). MS1). The acceptor 1853 inputs the transmission terminal information 1870 (FIG. 298) to the user service server 1855 together with the transmission identification information and the payment method (step MS2). Here, the transmission terminal information 1870 includes information for connecting the multicast transmission terminal 1810-2 to the network node device 1801. In addition, the symbol "N1801" in the transmission terminal information 1870 represents the network node device 1801, and "T1810-2" represents the terminal 1810-2. The user service server 1855 transmits the transmission terminal information 1870 to the multicast management server 1857 together with the acquired transmission identification information and transmission fee payment method (step MS3), and the multicast management server 1857 receives the reception. The above information is held in the database (step MS4).

Next, a case in which the user of the terminals 1810-11, 1810-13, 1810-14, 1810-17, 1810-18 receives multicast data and the like will be described. These users 1852 request the receptionist 1854 to receive the multicast data or the like (step MS11). The acceptor 1854 inputs the reception terminal information 1871 to the user service server 1856 together with the user identification information and the reception fee payment method (step MS12). Here, the reception terminal information 1187 (FIG. 299) connects the multicast data reception terminals 1810-11 and 1810-13 to the network node apparatus 1803, and connects the terminal 1810-14 to the network node apparatus (Fig. 299). 1804, and includes information for connecting the terminals 1810-17 and 1810-18 to the network node device 1805. The symbol " N1803 " in the reception terminal information 1871 represents the network node device 1803, the symbol " T1810-11 " represents the terminal 1810-11, and other techniques are also the same.

The user service server 1856 transmits the reception terminal information 1871 to the multicast management server 1857 together with the obtained reception identification information or fee payment method (step MS13), and the multicast management server 1857 receives the reception. The above information is held in the database (step MS14). When the multicast management server 1857 receives both step MS4 and step MS14, the multicast management server 1857 assigns the multicast identification information ID-k to the set of the transmitting terminal information 1870 and the user terminal information 1871, and builds up the tree. It sends to the server 1859 (FIG. 294) (step MS18). The tree building server 1859 requests the cost list 1869 from the resource management server 1858 (step MS19), and acquires the cost list 1869 (step MS20). The tree building server 1859 uses the multicast tree structure calculation module 1859-1 (FIG. 294) to determine the multicast tree structure determined by the multicast identification information ID-k (FIG. 301), that is, the multicast tree structure. Determine the transmission communication path of the IP packet by the cast technique, and form the address management table additional information (FIGS. 302 to 305) or the route table additional information (FIGS. 306 to 308) to the network node device to form a tree construction server. It holds in 1818 (step MS21).

<< Building a Multicast Tree Structure with Tree Building Servers >>

Next, the tree construction server 1859 adds the address management table additional information 1811-2 to the address management table 1811-1 and the route table additional information 1817-2 to the route table 1817-1, respectively. 1861 (step MS22), the table management server 1861 reports the setting for the request (step MS25), and the tree construction server 1859 sends the address management table addition information 1813-2 to the address management table. 1813-1 requests the table management server 1862 to add the address management table additional information 1814-2 to the address management table 1814-1 and the route table additional information 1818-2 to the route table 1818-1, respectively. (Step MS23). Then, the table management server 1862 reports the setting for the request (step MS26), and the tree construction server 1859 sends the address management table additional information 1815-2 to the address management table 1815-1, and the route table additional information. The table management server 1863 is requested to add 1819-2 to the route table 1819-1, respectively (step MS24), and the table management server 1863 reports the setting for the request (step MS27). Here, the table management server 1863 is connected to a router close to the network node device. The meaning of the address management table addition information and the route table addition information will be described in the flow of IP packet transmission. When the tree construction server 1859 confirms the completion of the steps MS25 to MS27, the tree construction server requested in step MS18 is completed by means of adding multicast information to the address management table in the network node device or the route table of the router. It reports to the multicast management server 1857 (step MS28). With the above procedure, the first half of the terminal-to-terminal communication connection control for multicast communication, that is, the construction of the multicast tree structure is completed.

<< Multicast Tree Structure >>

The meaning of the multicast tree structure shown in FIG. 301 is as follows. When the external IP packet sent from the terminal 1810-2 reaches the network node device 1801, the external IP packet becomes an internal IP packet, and the internal IP packet branches in two directions of the router 1807 and the router 1809, and the router Internal IP packets arriving at 1807 pass through router 1807 and then through router 1808 to reach network node device 1803. The other internal IP packet arrives at the router 1809, and the router 1809 sends the internal IP packet to two directions, namely, the network node devices 1804 and 1805. The network node device 1803 decapsulates the received internal IP packet, restores the external IP packet, and sends the restored external IP packet to the terminals 1810-11 and 1810-13. The network node device 1804 decapsulates the received internal IP packet, restores the external IP packet, and sends the recovered external IP packet to the terminal 1810-14. The network node device 1805 decapsulates the received internal IP packet, restores the external IP packet, and sends the restored external IP packet to the terminals 1810-17 and 1810-18. As described above, in the multicast communication, since the IP packet is transmitted in the communication path represented by the tree structure type, the shape of the communication path is called a multicast tree structure.

<< Construction of tree structure by multicast technique >>

In steps MS22 to MS24, the communication from the tree building server 1859 to the table management servers 1861 to 1863 is TCP communication (connection communication) with high communication reliability. However, a plurality of table management servers are connected to a plurality of routers in the IP transmission network, and share the new setting and record rewriting function of the address management table of the network node device and the route table of the router. In the present embodiment, the number of routers 1807 to 1809 is small (three), but the number of routers in the IP transport network is large, for example, hundreds of thousands of routers, and another embodiment in which the number of table management servers is considerably larger. Can assume

In such a case, transmitting the address management table additional information or the route table additional information from the tree building server to the plurality of table management servers is excessively disadvantageous due to the excessive traffic. For this reason, a record of a route table for transmitting address management table addition information and route table addition information from the tree construction server to the 100,000 routers is set in each router at the time of constructing the IP transmission network. However, the entire communication record of each router has a multicast tree structure to transmit IP packets. In this way, it is possible to suppress an excessive amount of communication for transmitting address management table additional information and route table additional information from the tree construction server to the plurality of routers.

<< Address Management Table >>

Referring to FIGS. 309 to 311, the first row of the address management table 1811 includes address management additional information 1811-2, and the first row of address management table 1813 includes the address management additional information 1813-2. Is included, the first row of the address management table 1814 includes address management additional information 1814-2, and the first row of the address management table 1815 includes the address management additional information 1815-2.

Internal IP address " I01 " is assigned to the network node device 1801 side end of the communication line 1822 in Fig. 309, and internal IP is given to the network node device 1803 side end of the communication line 1826-1 in Fig. 311. Addresses " I20 " and " IM2 " are given, and internal IP addresses " I22 " and " IM2 " are given to the network node device 1803 side end of the communication line 1826-2, and the communication line 1826-3 is provided. Internal IP addresses " I24 " and " IM2 " are assigned to the network node device 1804 side ends of the network node device 1804, and internal IP addresses " I27 " and " IM2 " "," And internal IP addresses " I28 " and " IM2 " are given to the network node device 1805 side end of the communication line 1826-5. Here, the internal IP address "IM2" is an embodiment of an address used for multicast.

<< How to express address management table >>

The description order of the record internal items in the address management tables 1811 to 1815 is shown in the prior art description by the order of the record internal items in the order of "E1, E2, I1, I2". In this embodiment, the order of the items is "I1, E1. , E2, I2 ", but the position is changed, but only the difference in the notation, there is no essential difference. The IP packet 1830 sent out from the terminal 1810-2 having the IP address "E01" reaches the network node device 1801 via the communication line 1822. The destination address " M2 " of the IP packet 1830 is a multicast external IP address, and is specifically, for example, " 224.1.2.3 ", where " 224 " means a multicast address of the IETF specification. As a specific numerical value of the multicast internal IP address "IM2", the value of "225.1.2.3" is mentioned, for example.

<< Route table of router >>

Referring to Fig. 310, route tables 1817 to 1819 are included, and a communication line for transmitting the received IP packet is written. The second row of the route table 1817 includes route table additional information 1817-2, and the second row of the route table 1818 includes route route additional information 1818-2, and the second row of route table 1819. The row contains route table additional information 1918-2. For example, in the case of the second row record of route table 1817, the IP packet whose destination IP address is " IM2 " is the communications line 1824-1 designated by the logical communication line name G12, and the route of the route table 1818. In the case of the second record, the IP packet whose destination IP address is " IM2 " is the communication line 1825 designated by the logical communication line name G27. In the second row of the route table 1819, "IM2" and "G21, G22" are written, and an IP packet whose destination IP address is "IM2" is a communication line 1824 designated by the logical communication line name G21. -2) and the communication line 1824-3 designated by the logical communication line name G22.

<< Transmission of IP Packets >>

Next, a series of IP packet transmission steps starting from the transmission of the external IP packet 1830 from the terminal 1810-2 will be described, but 1800-1 in FIG. 312 shows transmission and reception of IP packets in the IP transmission network 1800. . When the terminal 1810-2 transmits the external IP packet 1830 to the communication line 1822 (step D1 in FIG. 312), and the network node device 1801 receives the external IP packet 1830, the IP packet ( The internal IP address assigned to the terminal (logical terminal) of the communication line 1822 input by 1830 confirms "I01" and the destination external IP address "M2" of the IP packet 1830, and the address management table 1811 Search inside, first searching for a record in which the sender internal IP address is "I01" and then the destination external IP address is "M2" (first IP packet acceptance check), and in the searched record. It is checked whether the source external IP address " E01 " in the IP packet 1830 is included (second IP packet acceptance check).

In this example, a record including "I01, E01, M2, IM2, G02, G03, 0" in the first row from the top of the address management table 1811 is found, and the IP addresses "I01" and "IM2" in this record are found. Using IP, the source IP address is " I01 " and the destination IP address forms " IM2 " (encapsulation of the IP packet), and the internal IP packet is stored in the communication line 1823-1 for the logical communication line name G02 after encapsulation. It sends out as 11831-1 (step D2), and it sends out as an internal IP packet 1831-2 to the communication line 1823-2 for the logical communication line name G03 after encapsulation (step D3). In the above procedure, when the destination IP address of the external IP packet 1830 is not included in the address management table 1811, the external IP packet 1830 is discarded (first IP packet acceptance check). Further, checking whether the detected record contains the source IP address " E01 " in the IP packet 1830 can be omitted. In this case, the second IP acceptance check is not performed.

Since the internal IP packet 11831-1 transmitted over the communication line 1823-1 reaches the router 1807, and the destination IP address of the internal IP packet 18311-1 is "IM2", the route table According to "IM2, G12" of the 2nd line of 1817, it is sent to the communication line 1824-1 for logical communication line names G12 as an internal IP packet 1831-3 (step D4). Here, the IP packet 11831-1 is copied to form an IP packet 1831-3. Since the internal IP packet 1831-3 reaches the router 1808, and the destination IP address of the internal IP packet 1831-3 is "IM2", the "IM2, G27" in the second row of the route table 1818. In response to this, the logical communication line name G27 is sent as an internal IP packet 1831-4 (step D5). Here, the IP packet 1831-3 is copied to form an IP packet 1831-4. On the other hand, since the internal IP packet 1831-2 transmitted over the communication line 1823-2 reaches the router 1809, and the destination IP address of the internal IP packet 1831-2 is "IM2", According to "IM2, G21, G22" of the 2nd line of the route table 1819, it is sent to the communication line 1824-2 for the logical communication line name G21 as an internal IP packet 1831-5 (step D7), and also logical communication It is sent as an internal IP packet 1831-6 to the communication line 1824-3 for the line name G22 (step D8). Here, the IP packet 1831-2 is copied into an IP packet 1831-5 and an IP packet 1831-6. The route table 1817 to 1819 of the router and the route table of the network node device may have a known mask, but are omitted.

The internal IP packet 1831-4 reaches the network node device 1803 through the communication line 1825. Four items "IM2, M2, E01, I01" from the left of the record "IM2, M2, E01, I01, 0, F10, F12" in the first row of the address management table 1813 are 4 in the internal IP packet 1831-4. Since the four addresses " I01, IM2, E01, M2 " coincide with each other, the internal IP packet 1831-4 is decapsulated except for the IP header as described in the other embodiments, so that the external IP packet 1830 is performed. Is restored. The recovered IP packet is sent as an external IP packet 1832-1 to a communication line designated by output interfaces F10 and F12 in the first row record, that is, a communication line 1826-1 designated by output interface F10. (Step D11), it is then sent out to the communication line 1826-2 designated by the output interface F12 as an external IP packet 1832-2 (step D13). IP packet 1832-1 arrives at terminal 1810-11 and IP packet 1832-2 arrives at terminal 1810-13.

Similarly, the internal IP packet 1831-5 reaches the network node device 1804 via the communication line 1824-2. Four items "IM2, M2, E01, I01" from the left of the records "IM2, M2, E01, I01, 0, F14" in the first row of the address management table 1814 are four addresses in the internal IP packet 1831-5. Since it matches "I01, IM2, E01, M2", the inner IP packet 1831-5 is decapsulated except for the IP header as described in another embodiment, and the outer IP packet 1830 is restored. . The restored IP packet is sent as an external IP packet 1832-3 to a communication line designated by output interface F14 inside the first row record, that is, a communication line 1826-3 designated by output interface F14 (step). D14). The IP packet 1832-3 arrives at the terminal 1810-14.

The internal IP packet 1831-6 reaches the network node device 1805 through the communication line 1824-3. Four items "IM2, M2, E01, I01" from the left of the record "IM2, M2, E01, I01, 0, F17, F18" in the first row of the address management table 1815 are 4 in the internal IP packet 1831-6. Since the four addresses " I01, IM2, E01, M2 " coincide with each other, the internal IP packet 1831-6 is decapsulated except for the IP header as described in another embodiment, so that the external IP packet 1830 is decoded. Is restored. The restored IP packet is sent as an external IP packet 1832-4 to a communication line designated by output interfaces F17 and F18 inside the first row record, that is, a communication line 1826-4 designated by output interface F17. (Step D17), it is sent as an external IP packet 1832-5 to the communication line 1826-5 which the output interface F18 designates (step D18). IP packet 1832-4 arrives at terminal 1810-17 and IP packet 1832-5 arrives at terminal 1810-18.

<< Prevent flooding of ACK packets or NACK packets >>

In order for the terminal 1810-11 to report the reception of the external IP packet 1832-1 to the source terminal 1810-2, the terminal 1810-11 receives the source external IP address "M2" and the destination external IP address. Consider the case of forming an external IP packet 1833 that is "E01" and sending it to the communication line 1826-1 (step D21 in FIG. 312). When the network node device 1803 receives the external IP packet 1833, it confirms that the source IP address "M2" in the received external IP packet is a multicast address, and packet overflows the received external IP packet as it is. To the communication line 1843. The external IP packet sent to the packet overflow communication line 1843 is discarded. Similarly, when the network node apparatus 1804 receives an external IP packet from the terminal 1810-14 (step D22), or when the network node apparatus 1805 receives an external IP packet from the terminals 1810-17. Also in the case (step D23), the received external IP packet is transmitted to the communication line 1844 or 1845 as it is. External IP packets sent to packet overflow communication lines 1844 and 1845 are discarded.

As a result, all the multicast data receiving terminals can suppress the IP packet transmission of the terminal individual report to the multicast data source terminals, and as a result, prevent the massive flood of ACK packets or NACK packets inside the IP transmission network. Can

Next, a specific method of transmitting the received IP packet 1833 to the overflow communication line 1843 by the network node device 1803 will be described. The network node device 1803 has an internal IP address " IM2 " assigned to an end portion (logical terminal) of the communication line 1826-1 to which the IP packet 1835 is input, and the destination external IP of the IP packet 1833. Check the address "E01", search for the communication record in the address management table 1813, and first search for the communication record in which the sender internal IP address is "IM2" and then the destination external IP address "E01". It is checked whether the retrieved record includes the source external IP address "M2" in the IP packet 1833. In this case, this record is selected because all of the first to third address items of the first communication record "IM2, M2, E01, I01, 0, F10, F12" of the first row of the address management table 1813 match. Since the fifth item (internal packet output designation) of this communication record is "0", the IP packet 1833 is transmitted to the overflow communication line 1843 without encapsulating the IP packet 1833.

Further, in the case of transmitting external IP packets of the source IP address "M2" and the destination IP address "E01" from the terminals 1810-13, 1810-14, 1810-17, and 1810-18 to the network node apparatus, the above-mentioned. In the same order as one is transmitted to the overflow communication line of each network node device. As described above, even if the ACK packet for confirming that the multicast IP packet is received from the receiving terminal 1810-11 to the transmitting terminal 1810-2 cannot be passed through the network node apparatus 1803, As a result, congestion of the IP transmission network due to ACK implosion of ACK packets can be prevented. The use of IP packets on a packet overflow communication line will be described later.

Even when the network node apparatus 1803 receives the NACK packet from the terminal 1810-11 instead of the ACK packet, since the NACK packet can be discarded by the same principle, a large flood of the NACK packet can be prevented. The timing at which the terminals 1810-11 to 1810-19 transmit the NACK packet is determined in advance, for example, the IP packet transmission time by the multicast technique, and the IP packet is not delivered even when the scheduled time arrives. Transmits a NACK packet.

<< Realization of cable broadcasting >>

If the terminal 1810-2 is a voice transmitting terminal capable of transmitting digitized voice, and the terminals 1810-11, 1810-13, 1810-14, 1810-17, and 1810-18 are digitizing voice receiving terminals, IP Transmission of the packet 1830 becomes a wired voice broadcast. In addition, the terminal 1810-2 is a voice moving picture transmission terminal capable of transmitting a digitized voice moving picture, and the terminals 1810-11, 1810-13, 1810-14, 1810-17, and 1810-18 receive a digital voice moving picture. In the case of the terminal, transmission of the IP packet 1830 becomes a cable TV broadcast.

<< Modification of Multicast Tree Structure >>

The multicast tree structure can be modified by increasing or decreasing the multicast data receiving terminal. The acceptor 1854 obtains and holds the correspondence between the contents of the multicast service and the multicast identification information ID-k (k = 1, 2, ...) from the multicast management server 1857 in advance. The user 1852 requests the receptionist 1854 to receive the multicast service data using the terminal 1810-15 connected to the network node device 1804 (step MS31 in Fig. 313). The acceptor 1854 obtains the recipient identification information, the payment method, and terminal related information (using the network node device 1804 and the terminal 1810-15) from the user 1852, and obtains from the user 1852. The multicast identification information ID-k is specified from the contents of the multicast service. The acceptor 1854 inputs this information to the user service server 1856 (step MS32).

Next, the user service server 1856 transmits the obtained receiver identification information, bill payment method, terminal related information, and multicast identification information ID-k to the multicast management server 1857 (step MS33), and multicast management. The server 1857 holds the receiving terminal information in its database (step MS34). The multicast management server 1857 sends the multicast identification information ID-k and terminal related information (using the network node device 1804 and the terminal 1810-15) to the tree building server 1859 (step MS35). The tree building server 1859 requests the cost list from the resource administration server 1858 (step MS36), and obtains the cost list (step MS37).

The tree building server 1859 calculates a multicast tree structure in which the multicast identification information ID-k and the terminal related information are added by using the multicast tree structure calculation module 1859-1, and the address management table to the network node device. The additional information and the route table change information of the router are generated (step MS38), and held in the tree building server 1859. Next, the tree building server 1859 requests the table management server 1862 to add the address management table change information to the address management table 1814 of the network node device 1804 (step MS40), and the table management server 1862 reads the above. The setting for the request is reported (step MS41), and the tree building server 1859 reports to the multicast management server 1857 that the change of the multicast tree structure has been completed (step MS42). The multicast management server 1857 passes through the user service server 1856 (step MS43) and passes the acceptor 1854 (step MS44) to the user 1852 that the application procedure is completed from the user 1852 in step MS31. Report (step MS45).

It is assumed that the address management table 1814 is set by the table management server 1862. The address management table change information changes the sixth item "F14" in the first row of the address management table 1814 to "(F14, F15)", and the terminal 1810-15 connected to the logical communication line "F15" as a receiving terminal. Specifies to add. As a result, the record in the first row of the address management table 1814 is changed to " IM2, M2, E01, I01, 0, (F14, F 15) ".

In the case where the terminal 1810-11 cancels the reception of the multicast data, the user 1852 requests the acceptor to cancel the reception of the multicast data of the terminal 1810-11, and as a result, the address management table 1813 of FIG. The logical communication line "F10" connected to the terminal 1810-11 is deleted from the sixth item "(F10, F12)" of the first line "IM2, M2, E01, I01, 0, (F10, F12)". Specifies that As a result, the first row of the address management table 1813 is changed as "IM2, M2, E01, I01, 0, F12".

Incidentally, the present embodiment does not change the route table of the router 1807 or the like, but generates route table change information for the route tables of the routers 1807 to 1809 according to other modification request contents of the multicast tree structure. Alternatively, it is also possible to generate change information of the communication record for the address management tables of the other network node devices 1801 and 1802. In such a case, as in the case of newly setting the tree structure setting, other table management servers 1861 and 1863 are requested to change the route table of the router or the address management table of the network node device.

<< Freeing the Multicast Tree Structure >>

A procedure for releasing a multicast tree structure for terminating a multicast service will be described. The acceptor 1854 obtains and holds the correspondence between the contents of the multicast service and the multicast identification information ID-k (k = 1, 2, ...) from the multicast management server 1857 in advance. The sender 1851, such as multicast data, applies to the acceptor 1853 for the release of the multicast tree structure formed by the above procedure (step MS60 in Fig. 313). The acceptor 1853 inputs the release of the multicast tree structure to the user service server 1855 based on the transmission identification information and the multicast identification information ID-k (step MS61). The user service server 1855 transmits the release of the multicast tree structure to the multicast management server 1857 together with the transmission identification information (step MS62), and the multicast management server 1857 receives the received transmission identification information and the Based on the multicast tree structure release information (including the multicast identification information ID-k), the end of the multicast service is recorded in the database (step MS63). Next, the multicast management server 1857 instructs the tree building server 1859 to release the multicast tree structure which can be identified by the multicast identification information ID-k (step MS64).

The tree building server 1859 supplies additional information 1811-2, 1813-2, 1814-2, 1815- of the address management table of the network node device to the table management servers 1861 to 1863 based on the multicast identification information ID-k. 2) (FIGS. 302 to 305) are deleted from the address management tables 1811, 1813, 1814, and 1815, and additional information (1817-2, 1818-2, and 1819-2) of the router route table (FIGS. 306 to 308) is obtained. Instructions to be cleared from the route tables 1817, 1818, and 1819 (steps MS66 to MS68) are received (steps MS70 to MS72). Subsequently, the tree building server 1859, together with the multicast identification information ID-k, requests the resource management server 1858 to provide multicast communication with the resources in the IP transport network 1800 when setting up the multicast tree structure. Is returned to the resource management server 1858 (step MS73), and a report is received (step MS74). The tree building server 1859 reports completion of the release procedure of the multicast tree structure to the multicast management server 1857 (step MS77). In addition, the multicast management server 1857 passes through the user service server 1855 (step MS78) and passes the data transmission acceptor 1853 (step MS79) to complete the release procedure of the multicast tree structure (step MS79). ) (Step MS80). In addition, steps MS78 to MS80 may be omitted. The above procedure completes the release of the latter part of the terminal-to-terminal communication connection control by the multicast technique, that is, the release of the multicast tree structure.

<< Use of overflow communication line >>

A method of using the overflow communication lines 1843 to 1845 will be described. 1801 to 1805 of FIG. 314 are network node apparatuses, 1810-2 are terminals transmitting multicast data, 1810-11 to 1810-13 terminals receiving multicast data, and 1880 to 1882 are output lines 1843 to 1845. ) Are overflow communication line servers 1880-1882. The IP packet 1833 shown in Fig. 311 transmitted from the terminal 1810-11, that is, the IP packet having the source IP address " M2 " and the destination IP address " E01 " is the record " IM2, M2 " Is transmitted to the overflow communication line 1843 by the value " 0 " of the fifth item in " E01, I01, 0, F10, F12 ". The IP packet is transmitted on the overflow communication line when the internal packet output specification (fifth item) of the record is "0", and the IP packet is overflowed when the internal packet output specification is other than "0". It is not transmitted to the communication line.

Referring to Fig. 315, the IP packet with the sender external IP address " M2 " sent from the terminal 1810-11 reaches the network node device 1803 (step MC1), and the IP packet is an overflow communication line. (1843) Reach the overflow communication line server 1880 (step MC2). When an IP packet with a source external IP address "M2" is sent from the terminal 1810-12, the IP packet reaches the network node device 1803 (step MC3), and the IP packet is an overflow communication line ( The overflow communication line server 1880 is reached via 1843 (step MC4). When an IP packet having a source external IP address " M2 " is sent from the terminals 1810-13, the IP packet reaches the network node device 1803 (step MC5), and the IP packet is an overflow communication line 1843. The overflow communication line server 1880 is reached (step MC6).

In this case, the overflow communication line server 1880 receives a plurality of IP packets whose source external IP address " M2 ", that is, the source external IP address is a multicast IP address. When the terminals 1810-11 to 1810-13 transmit the IP packet, the terminal address of the sender is written in the payload portion of the IP packet. That is, the terminal 1810-11 sets the sender external IP address "E20", the terminal 1810-12 sets the sender external IP address "E21", and the terminals 1810-13 set the sender external IP address "E22", respectively. Since the rules are defined, the overflow communication line servers 1880 to 1882 can specify the external IP address of the source terminal using the IP address of the source terminal. In this way, when the sender terminals 1810-11 to 1810-13 have transmitted the ACK packet or the NACK packet, the terminal of the sender can be specified.

The overflow communication line server 1880 integrates the information from the three terminals acquired by the above method, passes through the network node device 1803 (step MD1), and also internal and network node devices (the IP transmission network 1800). After 1801 (step MD2), the transmission terminal 1810-2 of the multicast data can be notified (step MD3). In order to enable steps MD1 to MD3, in order to enable IP packet transmission between the overflow communication line server 1880 and the terminal 1810-2, the inside of the address management table 1811 in the network node device 1801 and the network are allowed. In the address management table 1813 in the node apparatus 1803, a record for performing IP encapsulation and decapsulation is set.

As a result of the above, the multicast data transmitting terminal 1810-2 can know whether the terminals 1810-11 to 1810-13 have received the multicast data (delivery confirmation function). At this time, the increase in the amount of communication in the IP transmission network 1800 due to the increase in the ACK packet and the NACK packet is suppressed.

The IP packet is transmitted from the overflow communication line server 1880 to the terminals 1810-11 to 1810-13 using the multicast address "M2" (steps ME1 to ME4), or the overflow communication line server 1880. From the IP address "E21", a record including the encapsulation address can be set in the address management table 1813, and the IP packet can be transmitted to the terminal 1810-12 (steps MF1 and MF2).

Referring to FIG. 316, the overflow communication line server 1880 can exchange information with the multicast transmitting terminal 1810-2 by transmitting and receiving IP packets (steps MG1 to MG3). The overflow communication line server 188 can exchange IP packets with the multicast data transmission terminal 1810-2 by sending and receiving IP packets (steps MH1 to MH3), and the overflow communication line server 1882 is an IP packet. Information exchange is possible with the multicast data transmission terminal 1810-2 by transmitting and receiving a packet (steps MI1 to MI3). In this way, the overflow communication line server transmits and receives IP packets to and from each multicast data receiving terminal connected to the network node device, and the multicast data transmitting terminal 1810-2 receives all the multicast data receiving terminals and IP. The need for transmitting and receiving packets can be eliminated, thereby reducing the workload of the multicast data transmitting terminal 1810-2. For example, when the terminal 1810-11 receives a request such as not receiving some IP packets of multicast data, the terminal 1810-11 can retransmit the missing IP packet past the overflow communication line server.

<< Other Embodiments of Address Management Table >>

The address management table 1811 of FIG. 309 can also be implemented in the form of the address management table 1811-5 of FIG. In this embodiment, the second item (source external IP address) of the record in the address management table 1811 is omitted to form the record in the address management table 1811-5. For example, the second item "E01" in the third row of the record "I01, E01, E26, I26, G03, F02" of the address management table 1811 is omitted, and the record "I01," in the third row of the address management table 1811-5 is omitted. E26, I26, G03, and F02 ". The IP encapsulation function of the network node device when the second item is omitted is also described in this embodiment.

In addition, the address management table 1811 of FIG. 309 can be implemented as the form of the address management table 1811-6 of FIG. This case uses a mask technique in IP encapsulation of an IP network node device.

When an external IP packet having a destination external IP address "E26" and a source external IP address "E01" is input from the communication line 1822 having the internal IP address of the terminal "I01", the first line from the top of the address management table 1811-6. And the third row of records, and for the first row, the "and" operation result of the destination external IP mask "M-t2" and the destination external IP address "E26" in the external IP packet is the first row. Check whether it matches the destination external IP address " M2x " in the record (Equation (9) below). In this case, the result of the "and" operation of the destination external IP mask "M-t26" and the destination external IP address "E26" in the external IP packet is the number in the third row for the third row of records. Check whether or not the new external IP address " E26x " matches (Equation 10 below). In this case it matches. The transmission source IP address is also compared by the following equation (11).

If ("M-t2" and "E26" = "M2x"). (9)

If ("M-t26" and "E26" = "E26x")... 10

If ("M-h01" and "E01" = "E01x")... (11)

According to the comparison result above, the third row of records is selected, and the inner records " I01 " and " I26 " in the third row of records are used to encapsulate to form an inner IP packet.

The address management table 1811 of FIG. 309 is divided into Tables 1811-7 and 1811-8, as shown in FIGS. 319 and 320, and can be implemented as a table on a memory in this form. That is, the record "I01, E01, M2, IM2, G02, G03, 0" of the first row of the address management table 1811 is replaced with the record "I01, E01, M2, IM2, MT-1, the first row of the table 1811-7. 0 "and the record" MT-1, G02, G03 "of the 1st line of Table 1811-8. That is, Table 1811-8 describes the branching of the multicast.

In summary, the information of the multicast service provider and the information of the multicast service purchaser are received via the user service server and used to set up the multicast tree structure. In addition, the tree construction server inquires the resource management server of the connection information and the communication line cost of the communication line between the network node apparatus and the router, and uses it to set up the multicast tree structure. Further, the tree building server notifies the plurality of table management servers of the address additional information to the address management table in the network node apparatus and the additional information to the route table server in the router to determine the multicast tree structure. In addition, multicast communication records are set in the route table of each router, and the address management table additional information or route table additional information for setting the tree structure for the multicast service is transmitted from the tree building server to the table management server using the multicast communication record. You can also do that.

In addition, the overflow communication line server communicates with the terminal connected to the network node device individually, and transmits multicast data if necessary, thereby realizing high reliability multicast. The digitized voice is transmitted from the voice transmitting terminal, and the plurality of digitized voice receiving terminals receive the digitized voice. Further, the digitized voice moving picture is transmitted from the digitized voice moving picture transmitting terminal, and the plural digitized voice moving picture receiving terminals receive the digitized voice moving picture. When the internal packet output designation in the address management table is "0", the IP packet is transmitted to the overflow communication line. When the packet overflow parameter is other than "0", the IP packet is not transmitted to the overflow communication line. . Further, the determination value "0" of the internal packet output designation may be a constant value or may be another specific value. When an IP packet including a multicast IP address as a source address is detected, the IP packet can be discarded to eliminate concentration of the IP packet to the source.

If the destination multicast address is registered in the address management table of the network node device as the first address registration check, and the destination multicast address in the header of the external IP packet entering the network node device is not registered in the address management table, By discarding the IP packet, the network node device prevents an unregistered IP packet from being mixed inside the IP transmission network. Similarly, when the sender address is registered in the address management table of the network node apparatus as the second address registration check, and the sender address in the header of the external IP packet entering the network node apparatus is not registered in the address management table, By discarding the IP packet, an unregistered IP packet is prevented from being mixed inside the IP transport network.

By not allowing the registration of the multicast address in the address management table of the recipient network node device, the ACK packet for acknowledging the receipt of the IP packet from the multicast IP packet receiver to the multicast IP packet sender cannot be passed through the network node device. Therefore, it is possible to prevent the congestion of the IP transmission network caused by the massive flooding of ACK packets or the massive flooding of NACK packets.

Also, do not allow the IP address of the router to be registered as a destination address, so that dangerous IP packets such as rewriting of multicast tables are not sent from outside the IP transport network to routers inside the IP transport network, or multicast inside the IP transport network is performed. Since the IP address registration of the target management server is not permitted, access to the management server inside the IP transmission network from the outside of the IP transmission network is disabled, thereby improving information safety. As the second address registration check, the source of the IP packet including the multicast data is restricted to prevent the cheating from occurring. In addition, when cheating is performed, it is easy to specify the source of the IP packet, and the information security of the IP transmission network can be improved.

18. Eighteenth embodiment for performing multicast communication:

This embodiment will be described with reference to FIGS. 321 to 324. Network node devices 1901 to 1905 and routers 1907-1 to 1907-4 are installed in the IP transport network 1900. The network node device and the router are connected directly or indirectly via the network node device or the router by an IP communication line. Terminals 1910-2 to 1910-70 having IP packet transmission / reception functions are connected to a network node device via an IP communication line. Reference numerals 1911 to 1915 denote address management tables of network node devices. Reference numerals 1911-3, 1911-4, 1911-5, 1912-3, 1912-4, and 1912-5 are multicast service proxy servers, and reference numerals 1913-3, 1913-4, and 1913-5 are overflow communication lines. Servers 1941 to 1945 denote overflow communication lines. In this embodiment, the terminal or the server may have a plurality of multicast IP addresses, in addition to having a unique IP address, and exchange information by exchanging IP packets.

<< sending terminal and sending office server >>

The terminals 1910-02 and 1910-05 are also transmission terminals for transmitting multicast data in a multicast service. Terminals 1910-06 and 1920-08 are also transmission administration servers for multicast services. The sending office server exchanges information with the multicast service proxy server by a database or an information processing mechanism, and shares a part of the information processing of the multicast data transmitting terminal.

<< Specify the output destination of the communication record >>

The fifth item in the communication record of the address management table is called the output destination specification of the internal IP packet, which is specified when the item value is other than "0", and when it is "0". It shall not be done. Similarly, the sixth item in the address management table communication record is called output destination designation of an external IP packet, and it is designated when the item value is other than "0", and is not specified when "0". For example, for the communication record " IM2, M2, E02, I02, 0, (F11 to F30, F91) " in the first row of the address management table 1913, the output destination designation of the internal IP packet is " 0 " The destination is not specified, indicating that the output destination of the external IP packet is " F11 to F30, F91 ", that is, F11 to F30 and F91 of the logical communication line. Here, F11 to F30 of the logical communication line are the communication lines 1960-11 to 1960-30, and the logical communication line F91 is the communication line 1960-91.

<< overflow communication line >>

The overflow communication line server collects IP packets such as ACK packets and NACK packets returned from the receiving terminal to the transmitting terminal via the overflow communication line, and transmits them to different multicast service proxy servers for each multicast address.

<< Transmission of Multicast IP Packets 1 >>

An external IP packet 1930 having a sender external IP address "E02" and a destination external IP address "M2" is sent from the terminal 1910-02 in FIG. 321 (step Q1 in FIG. 325), and the network node device 1901 is transmitted. On the first row of the address management table 1911, internal IP packets 1931-1 and 1931-2 are formed using the internal communication packets " I02, E02, M2, IM2, ..., 0 " -1 arrives at the router 1907-1 (step Q2), becomes the internal IP packet 1931-3, and reaches the network node device 1903 (step Q3). On the other hand, the internal IP packet 1931-2 arrives at the router 1907-2 (step Q4), and the internal IP packet 1931-2 is copied and branched into two at the router 1907-2, thereby making the internal IP packet 1931-4 arrives at network node device 1904 (step Q5), and internal IP packet 1931-5 arrives at network node device 1905 (step Q6).

When the network node device 1903 receives the internal IP packet 1931-3, using the communication record "IM2, M2, E02, I02, 0, F11 to F30, F91" in the first row of the address management table 1913, IP decapsulation of the inner IP packet 1931-3 restores the outer IP packet (same content as the outer IP packet 1930). Next, the restored external IP packet is sent to the terminals 1910-11 to 1910-30 and the multicast service proxy server 1911-3 according to the sixth item "F11 to F30, F91" of the communication record. (Steps Q7, Q7x). Here, the terminals 1910-11 to 1910-30 are assigned external IP addresses "E11" to "E30", and the multicast address "M2" is assigned to them. In addition, the multicast service proxy server 1911-3 is given a multicast address "M2" along with the external IP address "E91". The feature of this embodiment is that the multicast service proxy server 1911-3 receives data of the multicast service at approximately the same time as the terminals 1910-11 to 1910-30 (step Q7x).

When the network node device 1904 receives the internal IP packet 1931-4, using the communication record " IM2, M2, E02, I02, 0, F31 to F50, F93 " in the first row of the address management table 1914, IP decapsulation of the inner IP packet 1931-4 to restore the outer IP packet, and the restored outer IP packet is sent to the terminals 1910-31 to 1910-50 and the multicast service proxy server 1911-4. (Steps Q8 and Q8x). Here, the terminals 1910-31 to 1910-50 are given a multicast address "M2" together with the external IP addresses "E31" to "E50". The multicast service proxy server 1911-4 is assigned an external IP address "E93" and a multicast address "M2".

When the network node device 1905 receives the internal IP packet 1931-5, using the communication record "IM2, M2, E02, I02, 0, F51 to F70, F95" in the first row of the address management table 1915, IP decapsulation of the inner IP packet 1931-5 restores the outer IP packet. Then, the recovered external IP packet is sent to the terminals 1910-51 to 1910-70 and the multicast service proxy server 1911-5 (steps Q9 and Q9x). Here, the terminals 1910-51 to 1910-70 are given a multicast address "M2" together with external IP addresses "E51" to "E70". The multicast service proxy server 1911-5 is assigned an external IP address "E95" and a multicast address "M2".

<< sending IP packet by receiving terminal 1 >>

The terminals 1910-11 to 1910-70 respond to a variety of IP packets, for example, an ACK packet notifying a transmitting terminal of a normal reception, a NACK packet notifying a transmitting terminal of a reception failure, or the like, for example, replying to a question. Is sometimes transmitted to the sender terminal 1910-02 having an external IP address of "E02", and the procedure thereof will be described below. The sender address is an example in which the multicast IP address is "M2" and the destination IP address is "E02".

The terminals 1910-11 to 1910-30 form an IP packet to be transmitted to the terminal 1910-02 (step Q10), and send it to the network node apparatus (step Q11). When the network node device 1903 receives the external IP packet, the network node device transmits the communication record " IM2, M2, E02, I02, 0, (F11) in the first row of the address management table 1913 corresponding to the input external IP packet. to F30, F91) "is not specified, that is, since the fifth item of the communication record is" 0 ", the external IP packet is transmitted to the packet overflow output line 1943 as it is. (Step Q12).

<< Function of overflow communication line server 1 >>

The overflow line communication server 1913-3 receives the external IP packet 1946-1 (FIG. 328) from the overflow communication line 1943 (step MPS1 in FIG. 327), and the source of the external IP packet 1946-1. Confirm that the IP address is "M2" (step MPS2). Then, an IP packet 1946-2 to be sent to the multicast service proxy server 1911-3 that handles the multicast service specified by the multicast address "M2" is formed to send the IP packet (step) MPS3). Here, the source IP address of the IP packet 1946-2 is the IP address of the overflow communication line server 1913-3, and the destination IP address is the IP address of the multicast service proxy server 1911-3. Is "E91". The IP packet 1946-2 is sent out from the overflow communication line server 1913-3 (step Q13 in FIG. 325), and reaches the multicast service proxy server 1911-3 through the network node device 1903. (Step Q14). At this time, the communication records "I90, E90, E91, I91, ..., F90" of the twelfth row of the address management table 1913 and the communication records "I91, E91, E90, I90, ..., F91" of the tenth row are used. .

The multicast service proxy server 1911-3 is a case where the received IP packet is a NACK packet and requests to retransmit multicast data. Since the multicast service proxy server 1911-3 has received the multicast data classified by the IP address "M2" in advance in step Q7x, this multicast data can be used for the retransmission request. The multicast service proxy server 1911-3 retransmits the multicast data required for retransmission toward the network node device 1901 (step Q15), and the multicast data is sent to the terminals 1910-11 to 1910-30. (Step Q16). At this time, the communication records "I91, E91, M2, IM2, ..., F91" of the third row of the address management table 1913 and the communication records "IM2, M2, E91, I91, 0, F11 to F30" of the second row are Used.

<< Features of Multicast Service Surrogate Server 1 >>

The multicast service proxy server 1911-3 examines the contents of the received IP packet 1946-2, and collects the information in which the ACK packet indicating the acknowledgment is collected in a table or the like, or the reception failure notification received from the terminal. Form an IP packet that stores information that aggregates the NACK packet meaning in a list or the like, aggregated information such as individual reports of the terminal, and sends the packet to the sender terminal 1910-02, or sends a reply IP from the sender terminal 1910-02. A packet is received (steps Q41 to Q44 in FIG. 325). Here, the IP address of the IP packet is the external IP address "E91" of the multicast service agent server 1911-3 and the external IP address "E02" of the source terminal 1910-02, and the seventh line of the address management table 1913. Communication records "I91, E91, E02, I02, ..., F91" and communication records "I02, E02, E91, I91, ..., F02" in the second row of the address management table 1911 are used.

<< transmission of IP packet by receiving terminal 2 >>

The terminals 1910-31 to 1910-50 receive the multicast data in step Q8. The terminals 1910-31 to 1910-50 form an IP packet for use in acknowledgment (step Q20 in FIG. 325), and send it to the network node device 1904 (step Q21). When the network node device receives the external IP packet, the internal node of the communication record " IM2, M2, E02, I02, 0, (F31 to F50, F93) " in the first row of the address management table 1914 corresponding to the external IP packet is received. Since the packet output destination designation is not specified, that is, the fifth item of the communication record is "0", the external IP packet is transmitted to the packet overflow output line 1944 as it is without IP encapsulation (step Q22).

<< overflow communication line server 2 >>

The overflow line communication server 1913-4 receives the external IP packet from the overflow communication line 1944 and confirms that the source IP address of the external IP packet is "M2". Then, an IP packet is sent out to the multicast service proxy server 1911-4 that handles the multicast service specified by the multicast address " M2 ", and the IP packet is transmitted via the communication line 1914-1. Is sent to the multicast service proxy server 1911-4 (step Q24 in Fig. 325). In this case, the overflow line communication server 1913-4 and the multicast service proxy server 1911-4 are connected by the communication line 1914-1.

<< Function 2 of the multicast service proxy server >>

The multicast service proxy server 1911-4 previously received the multicast data in step Q8x. The multicast service proxy server 1911-4 retransmits the multicast data required for retransmission to the network node device 1904 (step Q25), and the multicast data is sent to the terminals 1910-31 to 1910-50. (Step Q26). At this time, the communication records "I93, E93, M2, IM2, ..., F93" of the third row of the address management table 1914 and the communication records "IM2, M2, E93, I93, 0, F31 to F50" of the second row are Used.

The multicast service proxy server 1911-4 examines the contents of the received IP packet and forms an IP packet storing ACK packet aggregation information, NACK packet aggregation information, terminal individual aggregation information, and the like. Or a reply IP packet is received from the source terminal 1910-02 (steps Q45 to Q48 in FIG. 325). Here, the communication records "I93, E93, E02, I02, ..., F93" of the seventh row of the address management table 1914 and the communication records "I02, E02, E93, I93, ..., F02" of the third row of the address management table 1911 are here. Is used.

<< IP packet transmission by receiving terminal 3 >>

The terminals 1910-51 to 1910-70 receive the multicast data in step Q9. The terminals 1910-51 to 1910-70 generate an IP packet for use in acknowledgment (step Q30 in FIG. 325), and send it to the network node device 1905 (step Q31). The network node device 1905 transmits the external IP packet to the packet overflow output line 1945 (step Q32). The overflow line communication server 1913-5 receives the external IP packet from the overflow communication line 1945, and sends the IP packet to the multicast service proxy server 1911-5 via the communication line 1915-1. ) (Step Q34 of FIG. 325).

The multicast service proxy server 1911-5 previously received the multicast data in step Q9x. The multicast service proxy server 1911-5 retransmits the multicast data required for retransmission to the network node device 1905 (step Q35), and the multicast data reaches the terminals 1910-51 to 1910-70. (Step Q36).

The multicast service proxy server 1911-5 examines the contents of the received IP packet, forms an IP packet that stores ACK packet aggregation information, etc., and sends it to the source terminal 1910-02, or the source terminal 1910-. 02) A reply IP packet is received (steps Q49 to Q52 in FIG. 325). In addition, the multicast service proxy server 1911-5 can exchange information by directly transmitting and receiving IP packets with the terminals 910-70 (steps Q38 and Q39). At this time, the communication records "I95, E95, E70, I70, ..., F95" in the ninth row of the address management table 1915 and the communication records "I70, E70, E95, I95, ..., F70" in the tenth row are used. In this case, the multicast service proxy server 1911-5 provides a service for directly communicating with the terminals 1910-70.

<< Send packet with multicast IP address "M5" >>

From the terminal 1910-05 of FIG. 322, an external IP packet 1932 having a source external IP address "E05" and a destination external IP address "M5" is sent out, and is encapsulated via an IP node device 1902 to be internally encapsulated. IP packets 1933-1 and 1933-2, and arrive at network node devices 1901 to 1905 via routers 1907-3 and 1907-4, respectively, where the internal IP packets are decapsulated and the terminal ( 1910-21 to 1910-30, terminals 1910-41 to 1910-50, and terminals 1910-61 to 1910-70. The sequence is shown in FIG. 326, the first of which differs from FIG. 325 in that the terminal 1910-05 becomes the transmitting terminal instead of the transmitting terminal 1910-02, instead of the routers 1907-1 and 1907-2. Routers 1907-3 and 1907-4 are used. The path through which the IP packet is transmitted is changed as shown in FIG.

As described above, the plurality of receiving terminals connected to the network node apparatus each have its own external IP address and at least one multicast IP address determined for each multicast service, so that one or more multicast services can be received. It is.

<< Outgoing Office Server >>

Second, among the major differences, the multicast service agent servers 1912-3 through 1912-5 transmit IP packets including the ACK aggregate information IP packet, NACK aggregate information IP packet, and aggregated information of individual terminals. 1910-08, and data transmitted from the transmission office server 1910-08 can be received. The transmitting office server 910-08 and the transmitting terminal 1910-05 also transmit and receive IP packets to exchange information (step R55 in FIG. 326). Transmission and reception of IP packets between the multicast service proxy server 1912-3 (IP address "E92") and the sending office server 1910-08 (IP address "E08") is performed in the fifth communication line of the address management table 1912. I08, E08, E92, I92, ..., F08 "and the communication record" I92, E92, E08, I08, ..., F92 "of the eighth line of the address management table 1913 are used. IP packet transmission and reception between the multicast service proxy server 1912-4 (IP address "E94") and the sending office server 1910-08 is performed by the communication records "I08, E08, E94, I94 of the 6th line of the address management table 1912." , ..., F08 "and the communication record" I94, E94, E08, I08, ..., F94 "of the 8th line of the address management table 1914 are used.

IP packet transmission and reception between the multicast service proxy server 1912-5 (IP address "E96") and the sending office server 1910-08 is performed by the communication records "I08, E08, E96, I96 of the 7th line of the address management table 1912." , ..., F08 "and the communication record" I96, E96, E08, I08, ..., F96 "of the 8th line of the address management table 1915 are used. IP packet transmission and reception between the transmission office server 1910-08 (IP address "E08") and the transmission terminal 1910-05 (IP address "E05") is performed by the communication records " I08, E08 in the eighth line of the address management table 1912. " , E05, I05, ..., F08 "and the communication records" I05, E05, E08, I08, ..., F05 "of the ninth line are used.

<< Overflow Communication Line Server and Multicast Service Proxy Server >>

The function of the overflow communication line server and the multicast service proxy server is the same as the case where the multicast IP address is "M2". When the overflow communication line server 1913-3 inputs an IP packet from the overflow communication line 1943 (step MPS1 in Fig. 327), it is determined whether the multicast IP address of the IP packet is "M2" or "M5", or the like. It checks (step MPS2), distributes to the multicast service agent server 1911-3 and the multicast service agent server 1912-3, and transmits it (step MPS3).

<< New installation and cancellation of multicast IP address >>

The administrator of the IP transport network 1900 has the authority to rewrite the communication records of the address management tables 1911 to 1915 of the network node device. The communication record " I07, E07, M7, IM7, ..., 0 " used by the multicast service transmission terminal 1910-7 is added to the address management table 1911 in the network node device 1901 (where "M7" is multiplied). (Cast IP address) and route information of the multicast address " M7 " is added to the route table in the routers 1907-1 to 1907-4, and the terminal for receiving the multicast service is added to the address management table 1913 in the network node device 1903. 1910-11 to 1910-20) add the communication records " IM7, M7, E07, I07, 0, F11 to F20, F91-1 ". "M7" is the same multicast IP address as "M7", F11 to F20 are output line interfaces for accessing terminals 1910-11 to 1910-20, and F91-1 is a newly installed multicast service proxy server. Output line interface to connect to. The operation manager of the IP transmission network 1900 installs the multicast IP address "M7" in the terminals 1910-11 to 1911-20.

Similarly, the communication records " IM7, M7, E07, I07, 0, F31 to F40, F93-1 used by the multicast service receiving terminals 1910-31 to 1910-40 in the address management table 1914 in the network node device 1904. ", And communication records " IM7, M7, E07, I07, 0, F51 to F60, used by the multicast service receiving terminals 1910-51 to 1910-60 in the address management table 1915 in the network node device 1905; Add F95-1 ". Through the above procedure, the terminals 1910-11 to 1910-20, the terminals 1910-31 to 1910-40, and the terminals 1910-51 to 1910-60 can receive new multicast services. The terminal 1910-30 receives a multicast IP service which can be identified by the IP address " M5 ", and the communication records " IM5, M5, E05, I05, 0, (" F21 to F30, F92) ", the sixth item" (F21 to F30, F92) "and the communication record" IM5, M5, E92, I92, 0, (F21 to F30) "of the fifth row of the address management table 1913. Use the sixth item "(F21 to F 30)". Since the record "F30" corresponds to the terminal 1910-30, the record is changed. That is, the fourth communication line "IM5, M5, E05, I05, 0, (F21 to F29, F92)" of the address management table 1913 and the fifth communication record "IM5, M5, E92, I92, 0, ( F21 to F29) ". By changing the communication record described above, the terminal 1910-30 was able to cancel the multicast service identifiable by the multicast IP address "M5".

<< network node device connecting the sending office server >>

In the above embodiment, the transmitting terminal 1910-05 and the transmitting office server 1910-08 are connected to the same network node apparatus 1902, but are connected to the terminal node 1910-07 (network node apparatus 1901). The transmitting terminal 1910-05 causes the network node apparatus 1902 to newly set the IP address "E07" in the transmitting office server so that the terminals 1910-08 (IP address "E08") are not used as the transmitting office server. The sending office server 1910-07 may be connected to the network node device 1901 in the state of being connected to the network. In other words, the transmitting terminal and the transmitting office server can be connected to different network node devices.

In this case, the sending office server 1910-07, the multicast service agent servers 1912-3 to 1912-5 which transmit and receive IP packets, and the sending terminal 11910-05 set the IP address of the sending office server "E07". Change to Further, the record "I92, E92, E08, I08, ..., F92" in the eighth row of the address management table 1913 is changed to "I92, E92, E07, I07, ..., F92", and the eighth row of the address management table 1914 The record "I94, E94, E08, I08, ..., F94" is changed to "I94, E94, E07, I07, ..., F94", and the record "I96, E96, E08, I08, ..., F96 "is changed to" I96, E96, E07, I07, ..., F96 ".

Further, the communication record "I07, E07, E05, I05, ..., F07" between the transmission office server 1910-07 and the transmission terminal 1910-05, the transmission office server 1910-07, and the multicast service proxy server Communication records between (1912-3 and 1912-5) "I07, E07, E92, I92, ..., F07", "I07, E07, E94, I94, ..., F07", "I07, E07, E96, I96, ..., F07 "is added to the address management table 1911. In addition, records " I05, E05, E07, I07, ..., F05 " in the address management table 1912 for transmitting terminal 1910-05 and the transmitting office server 1910-07 are added to the address management table 1912. Communication with the communication records "I08, E08, E05, I05, ..., F08" between the terminal 1910-08 and the transmitting terminal 1910-05 or the multicast service agent servers 1912-3 to 1912-5. Records "I08, E08, E92, I92, ..., F08", etc. are erased.

<< Integration of sending terminal and sending office server >>

In addition, by assigning the same IP to the transmitting terminal 1910-02 and the transmitting office server 1910-06, the function of the transmitting office server 1910-06 is included in the function of the transmitting terminal 1910-02 to integrate. It may be. Here, the functions of the transmission office server 1910-06 and the functions of the transmission terminal 1910-02 are classified by TCP port number or UDP port number.

<< Variation of Overflow Communication Line >>

The overflow communication line server 1913-5 of FIG. 324 divides and transmits the multicast IP address of the IP packet received from the overflow communication line 1945 into communication lines 1915-1 and 1915-2. As a modification of this means, a method of installing an overflow IP packet classification function unit will be described. In FIG. 329, reference numeral 1905-1 denotes a network node device, reference numeral 1915-1 denotes an address management table, reference numeral 1925-1 denotes an external circuit interface unit, and reference numeral 1911-5X denotes a multi-function having the same function as 1911-5 of FIG. The multicast service proxy server specified by the cast IP address "M2", reference numeral 1912-5X, is a multicast service proxy server specified by the multicast IP address "M5" having the same function as 1912-5 in FIG. Reference numeral 1913-5X denotes an overflow IP packet classification function having a function similar to that of the overflow communication line server 1913-5.

The overflow IP packet classification function, when the sender receives an external IP packet that is a multicast IP address, determines the sender multicast IP address when the specified value of the overflow parameter of the communication record is "0". Transmit to service proxy server via communication line 1915-1X or 1915-2X.

<< Realization of cable broadcast or media distribution communication system >>

Multicast data includes so-called multimedia data such as digitized voice and fax data, still images and moving pictures. When the terminal 1910-02 is a voice transmitting terminal capable of transmitting digitized voice and the terminals 1910-11 to 1910-70 are digitizing voice receiving terminals, transmission of the IP packet 1930 is performed by wired voice broadcasting transmission. Thus, a wired voice broadcasting communication system using IP transmission can be realized. If the terminal 1910-02 is a voice moving picture transmission terminal capable of transmitting a digitized voice moving picture, and the terminals 1910-11 to 1910-70 are digital voice moving picture receiving terminals, the transmission of the IP packet 1930 is performed. The cable TV broadcast transmission can be used to realize a cable TV broadcast communication system using IP transmission. By the same method, a wired fax communication system using IP transmission for transmitting and receiving a digitized still image can be realized.

The digitized voice receiving terminal or the voice moving image receiving terminal can transmit an IP packet including the receiving terminal individual information such as listening to the received data (broadcast content) of the multicast data toward the transmitting terminal 1910-02. The multicast service proxy server can receive an IP packet from a plurality of receiving terminals, and transmit an IP packet including aggregated information, etc., in which the information contained in the IP packet is edited in a table or a short sentence, to the transmitting terminal or the transmitting office server. have. In addition, the transmitting terminal or the transmitting office server can return the IP packet including a comment on the result of receiving the IP packet including the aggregated information to the multicast service agent server, and as a result, the multicast data transmitting side and the multicast data. A wired broadcasting communication system capable of exchanging information on the receiving side of the terminal is realized. As described above, the multicast proxy server is mediating the exchange of information between the multicast data transmitting side and the multicast data receiving side. When the media to be transmitted are books, newspapers, music or video, the cable broadcasting communication system can realize a book delivery communication system, a newspaper delivery communication system, a music delivery communication system, and a video delivery communication system as a multicast service. Here, video refers to information consisting of audio and moving pictures which are digitized and stored in video tapes, CDs, DVDs, and the like.

<< Summary >>

A terminal connecting to a network node device via an IP communication line can have a unique external IP address and at least one multicast IP address determined for each multicast service, so that a plurality of transmitting terminals can be provided. In addition, the multicast data transmitted by the transmitting terminal of the multicast data is transmitted inside the IP transmission network and delivered to a plurality of terminals, thereby allowing the terminal to receive one or more multicast services. The receiving terminal may request a IP transmission network operator to newly install or cancel a multicast IP address for each multicast service. The multicast service proxy server can access one or more network node devices.

The multicast service proxy server is an IP packet including ACK packet aggregation information received from one or more terminals connected to the network node apparatus to which the multicast service proxy server is connected, NACK packet aggregation information, or information that aggregates individual terminal information. Can be transmitted to a transmitting terminal or a transmitting office server that performs the multicast service. The multicast service is capable of high quality services in accordance with improvement requests such as acknowledgment notification (ACK packet) and bad reception notification (NACK packet) of multicast data. By suppressing, an increase in the amount of communication in the IP transport network can be suppressed. In addition, it is possible to prevent the distribution of multicast data that is not contracted with a telecommunications company, thereby making it easy to charge a fee for the use of the multicast service.

The multicast service proxy server can exchange information by transmitting and receiving IP packets with a transmitting terminal or a transmitting office server that is performing the multicast service to which the multicast service proxy server is connected. The multicast service proxy server receives the multicast data transmitted from the source terminal and holds it therein, and the multicast service proxy server uses the multicast function of the network node device to store the multicast data. The server may transmit to a terminal connected to the network node apparatus to which the server is connected. The multicast service proxy server can exchange information by sending and receiving a communication record with an IP packet with a specific terminal set in the network node apparatus.

IP encapsulation inside a communication record specifying IP encapsulation and IP de-encapsulation methods, if no internal IP packet destination designation is specified, and without external encapsulation when no internal IP packet destination designation is specified. Output an IP packet to an external IP packet overflow communication line. The overflow communication line server receives external IP packets not encapsulated via the external IP packet overflow communication line, and transmits the information contained in the external IP packets to the multicast service proxy server via the network node device. It is supposed to be.

The overflow communication line server receives the IP-encapsulated external IP packet via the external IP packet overflow communication line, and communicates the information contained in the IP packet with the overflow communication line server and the multicast service proxy server. It is intended to transmit to a multicast service proxy server via a circuit. An overflow IP packet distribution function for connecting to an external IP packet overflow communication line is included. IP decapsulation when the external IP packet destination designation value in the communication record is specified, and internal IP packet overflow without IP decapsulation when the external IP packet destination designation is not specified It is output to the communication line.

19. Ninth Embodiment for Multicast Communication:

This embodiment has a feature that the network node device does not perform IP encapsulation, which will be described with reference to FIGS. 330 to 333.

Network node devices 2001 to 2005 and routers 2007 to 2009 are installed in the IP transport network 2000. The network node device and the router are connected directly or indirectly via the network node device or the router by an IP communication line. Reference numerals 2011 to 2015 denote address management tables of network node apparatuses, and register IP addresses of terminals connected to the network node apparatus via a communication line. Reference numerals 2016 to 2020 denote route tables of network node devices, and reference numerals 2021 to 2023 denote route tables of routers. The terminals 2025 to 2039 have an IP packet transmission and reception function and are connected to a network node device via an IP communication line. Reference numerals 2045 to 2049 denote overflow communication lines through which unexpected IP packets are output. Reference numeral 2050 denotes a multicast service proxy server. The terminal 2026 is also a transmitting terminal for transmitting multicast data in a multicast service. Multicast data includes so-called multimedia data such as digitized voice and fax data, still images and moving pictures. The terminal 2027 is also a transmitting office server for the multicast service.

<< Transmission of IP Packets >>

Next, a series of IP packet transmission steps that begin with the transmission of the external IP packet 2040 by the transmitting terminal 2026 will be described. The terminal 2026 transmits an external IP packet 2040 having a source external IP address "E02" and a destination IP address "M2" to the communication line 2051 (step DD1 in FIG. 333), and the network node device 2001 Checks whether the source IP address " E02 " of the received IP packet 2040 is registered in the address management table 2011 (IP packet acceptance check), and in this case, the logical communication line name " F02 " Since the pair of IP addresses "E02" is registered as the records "F02, E02" of the second row of the address management table 2011, the IP packet 2040 is accepted. In addition, in the case where it is not registered, the received IP packet is transmitted to the packet overflow communication line 2045 as it is, and the IP packet is discarded.

Next, for the record "Msk-m2, M2, G02, G03" of the first row of the route table 2016, the first item "Msk-m2" of the record and the destination IP address "M2" of the IP packet 2040. It is checked whether the result of the "and" operation of "matches the second item" M2 "of the record (Equation 12 below). In this case it matches. Here, the value of "Msk-m2" is a case of 255.255.255.255.

If ("Msk-m2") and "M2" = "M2"). (12)

Next, for the third item G02 and G03 of the record, the IP packet 2041 is sent to the communication line 2053 having the logical communication line name "G02" (step DD2), and the IP packet 2042 is sent to the logical communication. It sends out to the communication line 2054 with the line name "G03" (step DD3). IP packets 2041 and 2042 are both generated by copying IP packet 2040. In the above procedure, when the destination IP address " M2 " of the IP packet 2040 is not included in the route table 2016, the external IP packet 2040 is discarded (registration check of the multicast address).

The IP packet 2041 reaches the router 2007 and is sent as an IP packet 2043 to the communication line 2055 having the logical communication line name G12 according to the record " M2, G12 " in the second row of the route table 2021 ( Step DD4). The IP packet 2043 reaches the router 2008 and is sent as an IP packet 2034 to the communication line 2058 having the logical communication line name G27 according to the record " M2, G27 " in the second row of the route table 2022 ( Step DD5). On the other hand, the IP packet 2042 sent to the communication line 2054 arrives at the router 2009 and communicates with the logical communication line name "G21" in accordance with "M2, G21, G22" in the second row of the route table 2023. IP packet 2035 is sent to 2056 (step DD6), and IP packet 2036 is sent to communication line 2057 having the logical communication line name "G22" (step DD7). IP packets 2035 and 2036 are both generated by copying IP packet 2042. The route tables 2021 to 2023 of the router may have the same mask as that of the route table 2016 of the network node device.

The IP packet 2034 reaches the network node device 2003 through the communication line 2058. For the record "Msk-m2, M2, F10, F12, F22" of the first row of the route table 2018, the first item "Msk-m2" of the record and the destination IP address "M2" of the IP packet 2034. Check whether the result of " and " of " matches the second item " M2 " In this case it matches. Here, the value of "Msk-m2" is a case of 255.255.255.255.

If ("Msk-m2") and "M2" = "M2"). (13)

Next, for the third item F10, F12, F22 of the record, the IP packet 2038 is sent to the communication line 2060 having the logical communication line name "F10" (step DD11), and the logical communication line name "F12". The IP packet 2039 is sent to the "in communication line 2061" (step DD13), and the IP packet is sent to the communication line 2059 having the logical communication line name "F22" (step DD9). Terminals 2031 and 2033 receive multicast data via communication lines 2060 and 2061, respectively. The multicast proxy server 2050 holds the multicast data received via the communication line 2059 in an internal database.

The network node device 2004 receives the IP packet 2035 and performs the same procedure as the network node device 2003 using the records "Msk-m2, M2, F13" of the first row of the route table 2019. The IP packet 2040 from which the IP packet 2035 has been copied is sent to the communication line 2062 having the logical communication line name "F13" (step DD14). The network node apparatus 2005 receives the IP packet 2036, and is identical to the procedure of the network node apparatus 2003 using the records " Msk-m2, M2, F16, F17 " of the first row of the route table 2020. The IP packet 2041 copied from the IP packet 2036 is sent to the communication line 2063 and the IP packet 2042 to the communication line 2064, respectively (steps DD17 and DD18).

<< Prevent flooding of ACK packets or NACK packets >>

In order for the terminal 2031 to report to the transmitting terminal 2026 information related to reception of the IP packet 2038, that is, an ACK packet of a reception report or a NACK packet of a poor reception report, an individual report of the terminal, and the like, to the transmitting terminal 2026. An IP packet 2044 having "M2" and the destination external IP address "E02" is formed and sent to the communication line 2060 (step DD21 in FIG. 333). Similarly, in order for the terminal 2033 to report the reception of the IP packet 2039 to the transmitting terminal 2026, the communication line 2061 transmits an IP packet having a source external IP address "M2" and a destination external IP address "E02". Is sent to (step DD22).

When the network node apparatus 2003 receives the IP packet reported to the transmitting terminal 2026 sent by the terminal 2031 or 2033, the network node apparatus 2003 checks whether the source IP address "M2" of the IP packet is registered in the address management table 2013. In this case, since it is not registered, the received IP packet is transmitted to the packet overflow communication line 2059 as it is (step DD26).

In this way, it is possible to suppress the transmission of terminal individual report IP packets from all the multicast data receiving terminals to the multicast data transmitting terminals, and as a result, it is possible to prevent a large flood of ACK packets and NACK packets inside the IP transmission network.

<< Data sent by multicast proxy server >>

The multicast proxy server 2050 receives the multicast data transmitted from the terminal 2026 in step DD9 and holds it in an internal database. The multicast proxy server 2050 receives the multicast data from the terminals 2031 and 2033 in step DD21 and DD22. When retransmission of data is requested, the held multicast data is sent to the terminal 2031 via the network node apparatus 2003 (step DD27) (step DD28) or to the terminal 2033. This can be done (step DD29). At this time, the first line "Msk-m2, M2, F10, F12, F22" of the route table 2018 in the network node apparatus 2003 is used to transmit the multicast data.

<< Data transmission and reception between sending terminals >>

The multicast service proxy server 2050 transmits an IP packet storing the various types of aggregated information to the transmitting terminal 2026, or receives a reply IP packet from the transmitting terminal 2026 (steps DD41 to DD45 in FIG. 333). ). Here, the IP address of the IP packet is the IP address " E22 " of the multicast service agent server 2050 and the IP address " E02 " of the transmitting terminal 2026, and the communication record " F22, " E22 ", the record" Msk22, E22, F22 "of the 5th line of route table 2018, the communication record" F02, E02 "of the 2nd line of address management table 2011, and the record" Msk02 "of the 3rd line of route table 2016 , E02, F02 "are used. In this manner, the multicast service proxy server can exchange information by transmitting and receiving an IP packet with the transmitting terminal 2026 performing the multicast service connected to the multicast service proxy server.

<< Data transmission between sending office servers >>

The multicast service proxy server 2050 transmits an IP packet storing the formed aggregated information (ACK packet aggregated information, NACK packet aggregated information, individual terminal information) to the transmitting office server 2027, or the transmitting office server ( A reply IP packet may be received from 2027 (steps DD46 to DD50 in FIG. 333). Here, the IP address of the IP packet is the IP address " E22 " of the multicast service agent server 2050 and the IP address " E03 " of the transmitting office server 2027, and the communication record " F22, " E22 ", the record" Msk22, E22, F22 "of the 5th line of route table 2018, the communication record" F03, E03 "of the 3rd line of address management table 2011, and the record" Msk03 "of the 4th line of route table 2016 , E03, F03 "are used. In this manner, the multicast service proxy server can exchange information by transmitting and receiving IP packets to and from a transmitting office server that performs the multicast service to which the multicast service proxy server is connected.

<< Information exchange between sending terminal and sending office server >>

The transmitting terminal and the transmitting office server can exchange information for performing the multicast service by exchanging IP packets (step DD51 in FIG. 333). In addition, the same IP is provided to the transmission terminal 2026 and the transmission office server 2027, and the function of the transmission office server 2027 can be included in the function of the transmission terminal 2026, and it can integrate. Here, the function of the transmission office server 2027 and the function of the transmission terminal 2026 are distinguished by a TCP port number or a UDP port number.

<< network node device connecting the sending office server >>

In this embodiment, the transmitting terminal 2026 and the transmitting office server 2027 are connected to the same network node apparatus 2001, but are connected to the network node apparatus 2002 (the terminal 2028 (IP address "E04")). May be newly set in the transmission office server, and the terminal 2027 may not be used as the transmission terminal. In other words, the transmitting terminal and the transmitting office server may be connected to different network node devices. In this case, the transmitting office server 2028, the multicast service proxy server 2050 for transmitting and receiving IP packets, and the transmitting terminal 2026 transmit and receive IP packets using the IP address of the transmitting office server as "E04".

<< Variant of Network Node Device >>

The network node device 2001 of FIG. 330 can be implemented by separating the address management module 2090 and the router 2091 shown in FIG. However, the address management module 2090 and the router 2091 can exchange information via the line 2092. The address management table 2011x in the address management module 2090 includes the same information as the address management table 2011 in the network node device 2001, and the route table 2016x in the router 2091 is the same information as the route table 2016 in the network node device 2001. It includes. The address management module 2090 is realized as a server or a hardware module realized in a personal computer or the like.

<< IP packet transmission using address management module >>

An IP packet transmission in the IP transmission network 2000 will be described with reference to FIG. 334. The terminal 2026 transmits an external IP packet 2040 having a sender external IP address "E02" and a destination IP address "M2" to the communication line 2051, and the router 2091 via the communication line 2051. An external IP packet 2040 is received, and the received external IP packet 2040 is transmitted to the address management module 2090 via the line 2092. The address management module 2090 checks whether the source IP address " E02 " of the received IP packet 2040 is registered in the address management table 2011x. In this case, it is confirmed that the pair of logical communication line name "F02" and the IP address "E02" of the communication line 2051 is registered as the records "F02, E02" of the second line of the address management table 2011x. Inform the confirmation result. The router 2091 receives the IP packet 2040 according to the report of the address management module 2090. In the case where the IP packet is not registered, the received IP packet is transmitted to the packet overflow communication line 2045 as it is and discarded.

Next, the router 2091 determines, for the first record "Msk-m2, M2, G02, G03" of the first row of the route table 2016x, the first item "Msk-m2" and the number of IP packets 2040 of the record. Check whether the result of the "and" operation of the new IP address "M2" matches the second item "M2" of the record (Equation (14) below. In this case, it matches. Here, the value of "Msk-m2" is The case is 255.255.255.255.

If ("Msk-m2") and "M2" = "M2"). (14)

Next, for the third item G02 and G03 of the record, the IP packet 2041 is sent to the communication line 2053 having the logical communication line name "G02", and the IP packet 2042 is sent to the logical communication line name "G03". To the communication line 2054.

The network node device 2003 of FIG. 332 may be replaced by a combination of an address management module and a router having the same function as described above. Here, the substitute address management module includes an address management table including the same information as the address management table 2013, and the substitute router includes the same information as the route table 2018. By the same principle, the network node apparatus 2004 and 2005 can be replaced by a combination of an address management module and a router having the same function as described above, and the network node apparatus 2004 and 2005 can be replaced with the address management table or the route table included in the network node apparatus 2004 to 2005, respectively. Make sure to include the information.

<< Realization of cable broadcasting and media distribution communication system >>

When the terminal 2026 is a voice transmitting terminal capable of transmitting digitized voice and the terminals 2031 to 2039 are digitizing voice receiving terminals, the transmission of the IP packet 2040 is a wired voice broadcasting transmission and uses IP transmission. A wired voice broadcast communication system can be realized. In addition, when the terminal 2026 is a voice moving picture transmission terminal capable of transmitting a digitized voice moving picture, and the terminals 2031 to 2039 are digital voice moving picture receiving terminals, the transmission of the IP packet 2040 is a wired TV broadcast transmission. A wired TV broadcast communication system using IP transmission can be realized. By the same method, a wired fax communication system using IP transmission for transmitting and receiving a digitized still image can be realized. The digitized voice receiving terminal and the voice moving image receiving terminal can transmit an IP packet including the receiving terminal individual information such as listening to the received data (broadcast content) of the multicast data toward the transmitting terminal 2026, and the multicast service. The surrogate server can receive an IP packet from a plurality of receiving terminals, and transmit an IP packet including aggregated information, etc., in which information contained in the IP packet is edited in a table or short sentences, to the transmitting terminal or the transmitting office server. In addition, the transmitting terminal or the transmitting office server can return the IP packet including a comment on the result of receiving the IP packet including the aggregated information to the multicast service agent server, and as a result, the multicast data transmitting side and the multicast data. A wired broadcast communication system capable of exchanging information on a receiving side of a terminal can be realized. As described above, the multicast proxy server is mediating the exchange of information between the multicast data transmitting side and the multicast data receiving side. When the media to be transmitted are books, newspapers, music or video, the cable broadcasting communication system can realize a book delivery communication system, a newspaper delivery communication system, a music delivery communication system, and a video delivery communication system as a multicast service. Here, video refers to information consisting of audio and moving pictures which are digitized and stored in video tapes, CDs, DVDs, and the like.

<< Summary >>

The terminal is connected to a router that connects an address management module via a communication line, and registers a sender IP address in an address management table of the address management module, so that a sender IP address in a header of an IP packet entering the router is stored in the address management module. IP packets are sent if they are registered in the address management table, and if they are not registered, the IP packets are transmitted to the overflow communication line of the router to prevent unintended IP packets from entering the IP transmission network. Doing. If the destination multicast IP address in the header of the IP packet entering the router is not registered in the route table of the router, an unscheduled IP packet is transmitted by a method of transmitting the IP packet to an overflow communication line of the router. This prevents mixing into the IP transport network.

If the IP address of the terminal is registered in the address management table of the network node device, the IP packet is transmitted. If the IP address is not registered, the IP packet is transmitted to the overflow communication line, and the IP packet is discarded or multicast surrogate. Sent to the server. By not registering a multicast IP address in the address management table of the network node device, an ACK packet or acknowledgment status for acknowledging an IP packet acknowledgment notifying that a multicast IP packet receiver has received an IP packet directed to the multicast IP packet sender. This prevents NACK packets and individual reporting IP packets from passing through the network node device. When the destination multicast address is registered in the route table of the network node device, the destination multicast address in the header of the external IP packet entering the network node device is registered in the route table, and the IP packet is transmitted. If not registered, the network node device discards the IP packet to prevent an unexpected IP packet from being mixed into the IP transmission network.

The multicast service agent server receives the multicast data transmitted from the transmitting terminal and holds the multicast data therein, and the multicast service agent server uses the multicast function of the network node device to multicast the service agent. The server can transmit to the terminal connected to the network node apparatus to which the server is connected.

The multicast service is performed on an IP packet including ACK packet aggregation information, NACK packet aggregation information, and aggregation information of individual terminal information received from one or more terminals connected to the network node apparatus to which the multicast service proxy server is connected. A transmission can be made to a sending terminal or a sending office server.

The multicast service proxy server is capable of exchanging information by transmitting and receiving IP packets with a transmitting terminal or a transmitting office server that is performing the multicast service to which the multicast service proxy server is connected. The multicast service proxy server is configured to use the information included in the IP packet received via the IP packet overflow communication line.

Wired voice broadcasting communication system, wired TV broadcasting communication system, and wired fax communication using IP transmission by using voice transmitting terminal, voice moving image transmitting terminal and still image transmitting terminal capable of transmitting digitized voice, voice moving image, still image, etc. The system can be realized. The receiving terminal of the cable broadcasting can transmit an IP packet including the individual information of the receiving terminal toward the transmitting terminal and, as a result, can exchange information between the multicast data transmitting side and the multicast data receiving side. Can be realized. The multicast proxy server mediates the exchange of information between the multicast data sending side and the receiving side of the multicast data.

The multicast service is capable of high quality services in accordance with improvement requests such as acknowledgment notification (ACK packet) and bad reception notification (NACK packet) of multicast data. By suppressing, the increase in the amount of communication in the IP transport network can be suppressed. In addition, it is possible to prevent the distribution of multicast data that is not contracted with a telecommunications company, thereby making it easy to charge a fee for using a multicast service.

20. Twentieth Embodiment of Multicast Communication:

This embodiment will be described with reference to FIG. In the IP transmission network 2100, a management range 2101 of a communication company X and a management range 2102 of a communication company Y are formed, and further, network node devices 2103 to 2114 and routers 2115-1 to 2115-11. ), A router 2116 is provided. The network node device and the router are connected directly or indirectly via the network node device or the router by an IP communication line. Terminals 2117 to 2133 having an IP packet transmission / reception function are connected to a network node device via an IP communication line. Reference numerals 2140 to 2143 denote multicast P service agent servers, reference numerals 2144 to 2147 denote multicast Q service agent servers, and reference numerals 2148 to 2151 denote overflow communication line servers. Telecommunication company X and telecommunication company Y manage the router 2116 jointly. The network node devices 2103 to 2114 are all devices that have IP encapsulation and decapsulation functions, or are all limited to devices that do not have IP encapsulation and decapsulation functions. It demonstrates by an example.

<< Telecommunication company's sending terminal and sending office server >>

The electronic newspaper delivery service by a newspaper company is divided into a multicast P service and a news distribution service by a B station into a multicast Q service. Terminal 2117 is a multicast data transmission terminal managed by telecommunication company X, terminal 2118 is a transmission office server managed by telecommunication company X, and terminal 2120 is a multicast data transmission terminal managed by telecommunication company Y, terminal Reference numeral 2122 denotes a transmission office server managed by the communication company Y, and terminal 2123 is a terminal managed by the A newspaper company. The terminals 2117 to 2120 transmit the electronic newspaper prepared by the newspaper A to the sending office server 2118 of the communication company X or the sending office server 2122 of the communication company Y, and perform office communication communication regarding the delivery of the electronic newspaper. A multicast P service terminal to perform. The terminal 2119 is a terminal managed by broadcasting station B, and transmits the (voice moving image) TV news distribution service provided by broadcasting station B to the transmitting office server 2118 of the communication company X or the transmitting office server 2122 of the communication company Y. The terminal is a multicast Q service terminal that performs office communications for electronic newspaper delivery.

The transmission office server 2118 is representative of the telecommunication company X, and relates to the transmission of multicast data such as an electronic newspaper delivery, a TV news distribution service by a B station, and an electronic stock price guide service by a C securities company. The office work procedure is carried out, and the sending office server 2122 performs office work procedures related to the transmission of multicast data on behalf of the communication company Y.

<< Transmission of Multicast IP Packets >>

Electronic newspapers are stored as digital information in a number of IP packets and are called electronic newspaper IP packets. The newspaper A sends the electronic newspaper IP packet from the terminal 2123 of the newspaper A to the sending office server 2118 of the communication company X (step 2160 in Fig. 336). At this time, the electronic newspaper IP packet is a network node device 2111, a router 2115-10, 2115-7, 2115-6, 2116, 2115-5, 2115-3, 2115-1, and a network node device 2103. The transmission office server 2118 is reached via. The transmission of the electronic newspaper IP packet from the terminal 2123 to the transmitting office server 2118 may be performed by any of known UDP communication schemes (connectionless communication) or TCP communication schemes (connection communication).

The sending office server 2118 holds the received electronic newspaper IP packet in an internal database (step 2161). Next, the transmission office server 2118 transmits the received and held electronic newspaper IP packet to the transmission terminal 2117 (step 2162), and the transmission terminal 2117 holds the received electronic newspaper IP packet. At this time, the transmission of the electronic newspaper IP packet from the transmission office server 2118 to the terminal 2117 can be performed by either a UDP communication technique or a TCP communication technique.

The transmitting terminal 2117 transmits the held electronic newspaper IP packet to the network node device 2103 (step 2163). Here, the destination address is a multicast address "Mx". The sent e-newspaper IP packet is simultaneously transmitted inside the multicast-dedicated IP transmission network 2152 to reach the network node devices 2106 to 2108 (steps 2171 to 2174), and the terminal 2124 which is a receiving terminal of the e-newspaper IP packet. To 2128) (steps 2175 to 2177), and simultaneously to the multicast P service proxy servers 2140 to 2141 (step 2178).

When the terminals 2124 to 2125 transmit an ACK packet indicating that the electronic newspaper IP packet has been normally received or a NACK packet indicating that the IP packet is an error (step 2181), the ACK packet to the NACK packet are in charge of the electronic newspaper delivery service. Is transmitted to the multicast P service proxy server 2140 (step 2183). Similarly, when the terminals 2126 to 2127 transmit an ACK packet or a NACK packet indicating a reception state of an IP packet (step 2182), the ACK packet to NACK packet is transmitted to the multicast P service proxy server 2141 (step) 2184). The case where the ACK packet or the NACK packet is sent from the terminal 2128 is also the same in order.

The multicast P service proxy servers 2140 to 2141 retransmit the electronic newspaper IP packet to the terminals 2124 to 2127 as multicast data (steps 2185 and 2186). The multicast P service proxy servers 2140 to 2141 form an IP packet for reporting the reception status of the electronic newspaper IP packet and send it to the network node apparatuses 2106 to 2107 (step 2187), and the IP packet is transmitted to the IP transmission network 2152. ) And the transmission office server 2118 is reached via the network node device 2103 (step 2189).

The transmission office server 2118 managed by the communication company X can calculate the usage fee of the IP network 2101 managed by the communication company X using the information related to the delivery of the electronic newspaper IP packet in steps 2162 and 2189. The transmitting office server 2118 forms an IP packet including a report to the newspaper A from the information included in the content of the received IP packet, and transmits the IP packet formed in the terminal 2123 of the newspaper A (step 2190). ). Here, the IP packet is transmitted to the terminal 2123 via the network node device 2103, routers 2115-1, 2115-3, 2115-5, 2116, 2115-6, 2115-7, 2115-10, and 2111. To reach. The newspaper A receives the IP packet and checks the delivery status of the electronic newspaper IP packet requested to the communication company X.

The newspaper A company sends the electronic newspaper IP packet from the terminal 2123 of the newspaper A company to the transmission office server 2122 of the communication company Y after completing step 2160 (step 2164 in FIG. 336). At this time, the electronic newspaper IP packet reaches the transmission office server 2122 via the network node device 2111, the router 2115-10, and the network node device 2110. The sending office server 2122 holds the received electronic newspaper IP packet in an internal database (step 2165).

The sending office server 2122 is authenticated to the sending terminal 2120 that the sending office server 2122 is a regular sending office server having a qualification to send an electronic newspaper IP packet (step 2260). 2122 transmits the received and held electronic newspaper IP packet to transmission terminal 2120 (step 2166), and transmission terminal 2120 holds the received electronic newspaper IP packet. In step 2164, the terminal 2123 of the newspaper A company may be authenticated to the transmission office server 2122 of the telecommunication company Y by the fact that the terminal 2123 of the newspaper A company must be authentic.

The transmitting terminal 2120 transmits the held electronic newspaper IP packet to the network node device 2109 (step 2167). Here, the destination address is a multicast address "My". The sent e-newspaper IP packet is simultaneously transmitted inside the multicast-dedicated IP transmission network 2153 to reach the network node devices 2112 to 2114 (steps 2191 to 2194), and the terminal 2129 is a receiving terminal of the e-newspaper IP packet. 2133 to 2133) (steps 2195 to 2197), and simultaneously to the multicast P service proxy servers 2142 to 2143 (step 2198). When the terminals 2129 to 2133 transmit ACK packets or NACK packets indicating the reception status of the electronic newspaper IP packet (steps 2201 and 2202), the ACK packets to NACK packets are multicast P service agents in charge of the electronic newspaper delivery service. It is sent to the server 2142 or 2143 (step 2203 or 2204).

The multicast P service proxy servers 2142 to 2143 retransmit the electronic newspaper IP packet to the terminals 2129 to 2133 as multicast data (steps 2205 and 2206). The multicast P service proxy servers 2142 to 2143 form an IP packet for reporting the reception status of the electronic newspaper IP packet and send it to the network node devices 2112 to 2113 (step 2207), and the IP packet is transmitted to the IP transmission network 2153. ) And the transmission office server 2122 is reached via the network node device 2109 (step 2209).

The sending office server 2122 managed by the communication company Y calculates the usage fee of the IP network 2102 managed by the communication company Y, and reports the report to the newspaper A from the information included in the contents of the received IP packet. The formed IP packet is formed, and the formed IP packet is transmitted to the terminal 2123 of the A newspaper company (step 2210). Here, the IP packet reaches the terminal 2123 via the network node device 2110, the router 2115-10, and the network node device 2111. The newspaper A receives the IP packet and checks the delivery status of the electronic newspaper IP packet requested to the communication company Y. Even in the case of performing the multicast Q service, the same method as described above can be performed.

<< Certification procedure >>

The authentication procedure of step 2260 has various known techniques, and an example will be described with reference to FIG. 337. The transmitting office server 2122 and the transmitting terminal 2120 have a common function y = f (a, b) and a secret authentication key "K" inside. The transmission office server 2122 transmits the information "ID2122" which identifies the transmission office server 2122 to the transmission terminal 2120 (step 2160-1). The transmitting terminal 2120 receives the information "ID2122" identifying the transmitting office server 2122, generates a random number "R", calculates and retains C1 = f (K, R), and simultaneously transmits. The random number "R" is transmitted to the office server 2122 (step 2160-2). The transmission office server 2122 calculates C2 = f (K, R) using the received random number "R", the authentication key "K", and the function "f", and transmits "C2" to the transmission terminal 2120. (Step 2160-3). The transmitting terminal checks whether the generated and retained "C1" and the received "C2" match, and if it matches, it can confirm that the transmitting office server 2122 holds a regular authentication key "K". It is possible to authenticate that the sending office server 2122 is a regular sending office server.

<< variation >>

Referring to FIG. 338, the inside of the IP transport network 2100-1 includes a management range 2101-1 of the communication company X, a management range 2102-1 of the communication company Y, a network node device 2104-1, 2105-1, 2107-1 to 2114-1, routers 2230 and 2232, address management modules 2231 and 2233, routers 2115-1 to 2115-11, and routers 2116. The network node devices 2104-1, 2105-1, and 2107-1 to 2114-1 are all devices that do not have IP encapsulation and de-encapsulation functions, and their specific internal configurations are the same as those described by other embodiments. . The router 2230 and the address management module 2231 are connected by a line, and the router 2230 and the address management module 2231 are integrated to function as the network node device. Similarly, the router 2232 and the address management module 2233 are connected by a line and integrated together to function the same as the network node device. In this manner, the same multicast service as in the multicast service described with reference to FIGS. 335 to 336 can be performed.

The electronic newspaper IP packet is transmitted to the transmitting office servers 2118 and 2122 from the terminal 2123 of the newspaper A company providing a multicast service, and the transmitting office servers 2118 and 2122 transmit the received electronic newspaper IP packet to the IP transmission network. Distribution can be performed by the multicast technique to the reception terminals 2124 to 2133 via 2101-1 and 2102-1. The distribution result is reported to the transmitting office servers 2118 and 2122, and can charge the receiving terminals 2124 to 2133.

Note that the IP transport networks 2152 and 2153 need not be multicast-dedicated IP transport networks, and the multicast service described above in common with the IP phones, data transmissions, and IP transmissions for voice and video transmission described in the other embodiments. Can be carried out.

<< Setting of address management table and route table >>

The address management table or the route table of the router in the network node device inside the management range 2101 of the communication company X and the management range 2102 of the communication company Y sets a separate address management table or a route table of the router for each type of multicast service. Setting of a multicast tree structure), and the method described in another embodiment may be applied. In addition, the technique described in other embodiments, such as changing the multicast tree structure according to the increase or decrease of the multicast service user, or releasing the multicast tree structure due to the suspension of the multicast service, can be applied to this embodiment.

<< Cleanup >>

By the above-described method, a plurality of multicast services are performed using an IP transmission network connected to IP transmission networks of a plurality of communication companies. The multicast service provider may request the telecommunication company to act for the billing service. The multicast data is transmitted to the sending office server managed by the communication company X and the sending office server managed by the communication company Y. The sending office server of the communication company X communicates with the communication company X via the sending terminal of the communication company X. The multicast data is delivered to a plurality of terminals connected to the managing IP transmission network, and the transmitting office server of the communication company Y is connected to the IP transmission network managed by the communication company Y via the transmitting terminal of the communication company Y. The multicast data can be delivered to the terminal. The delivery result in the IP transport network managed by the communication company X or the communication company Y is collected by the sending office server of the communication company X or the communication company Y via the multicast service proxy server.

Method and device for controlling communication between terminals using IP transport network Any IP terminal, IP phone, or IP voice image device such as a multimedia terminal, i.e., a personal computer having an IP communication function, can be used. By connecting to one or more, it is possible to control the terminal communication connection for the terminal-to-device communication using the IP transmission network. In this case, the media router is installed outside the integrated IP transport network, and enables mutual communication such as information exchange between the multimedia terminals by using a host name consisting of a multimedia terminal identification phone number or the like via the integrated IP transport network. .

A telephone having a telephone number for a public switched telephone network is connected to a media router inside a LAN, and a terminal-to-terminal communication is possible by connecting a telephone within the LAN from a telephone connected to the public switched telephone network via an integrated IP transport network. Moreover, a single multimedia terminal can be used for an IP data multicast network or an IP base TV broadcasting network in a form of transmitting electronic data such as an electronic book or audio image data to a plurality of multimedia terminals serving as a transmitting source.

Claims (27)

delete The first access server, the second access server, the domain name server, and the operation management server are installed in the IP transport network and connected via a communication line in the IP transport network, and the first terminal and the second terminal are external to the IP transport network. And the first and second terminals are connected to the first and second terminal accommodating radios, respectively, and the terminal accommodating radios respectively transmit and receive the first and second radios via the first and second radio communication paths. Communication connection with the unit, the first and second wireless transmission and reception units, the first and second communication lines and the IP transmission network, The first terminal sends a connection request to the second terminal and a host name (TN-2) of the second terminal to the first access server, and the first access server sends the host name (TN-2). Presenting the IP address of the second terminal and the IP address of the second access server in charge of access control of the second terminal, and using the IP address to include the connection request. Sends an initial address message to the second connection server, the second connection server sends a connection request notification to the second terminal based on at least the connection request, and sends an address completion message to the first connection server, An in-call notification informing the start of response preparation from the second terminal arrives at the second connection server, and the second connection server forms a call progress message including the in-call notification. A first notification sent to the first connection server, the first connection server sends the in-call notification to the first terminal, a response notification notifying the response from the second terminal arrives at the second connection server, and the second connection The server forms a response message including the response notification and sends it to the first access server, and the first access server sends at least the response notification to the first terminal. A communication path for transmitting an IP packet transmitted by a terminal and a second terminal is determined, and the communication path is identified by a pair of host names of the first terminal and the second terminal. The first terminal and the second terminal includes a first terminal accommodating wireless device, a first wireless communication path, a first wireless transceiver, a first communication line, the communication path, a second communication line, a second wireless transceiver, and a second The communication path identified by the host name of the source terminal and the host name of the destination terminal is determined by performing the communication via the radio communication path and the second terminal accommodating radio apparatus, and at least through connection control procedures relating to the call and the response. A method for controlling access between terminals using an IP transmission network, characterized in that for losing. The first terminal and the second terminal are installed outside the IP transmission network and are connected to the first and second terminal accommodating radios, respectively, and the first and second terminal accommodating radios are respectively the first and the second wireless communication. Connected to the first and second wireless transceivers via a path, wherein the first and second wireless transceivers are respectively connected to the IP transmission network via the first and second communication lines, The first terminal transmits an IP packet including a connection request and at least the host name (TN-2) of the second terminal to the IP transmission network to request connection to the second terminal using a host name, The IP transmission network receives the IP packet including the connection request, sends an IP packet including a connection request notification to the second terminal based on the connection request, When the second terminal receives the IP packet including the connection request notification, the second terminal sends an IP packet including an in-call notification indicating the start of response preparation to the IP transmission network, and the IP transmission network includes the in-call notification. Receiving an IP packet, sending an IP packet including the in-call notification to the first terminal, the IP packet reaching the first terminal, The second terminal responds to the call and sends an IP packet including a response notification informing the response, and the IP transmission network, upon receiving the IP packet, transmits an IP packet including at least the response notification to the first terminal. In this case, the IP transmission network determines a communication path for transmitting IP packets transmitted by the first and second terminals therein, and the communication path includes a host name (TN-1) and the communication path. Identified by a set of host names (TN-2), The first and second terminals may include a first terminal accommodating wireless device, a first wireless communication path, a first wireless transceiver, a first communication line, the communication path, a second communication line, a second wireless transceiver, and a second radio. Perform communication via a communication path, a second terminal accommodating wireless device, When the IP transmission network receives an IP packet including a disconnect request from the first terminal or the second terminal, the IP transmission network releases the setting of the communication path, and when the terminal-to-terminal communication ends, the IP transmission network is a source of communication between the terminals. The host name and the communication time of the terminal and the destination terminal are recorded as communication management information or charging information, and are identified by a set of host names of the source terminal and the destination terminal at least through connection control procedures relating to calling and response. The communication path control method between terminals using the IP transmission network, characterized in that the communication path is determined. The first terminal and the first terminal accommodating wireless device is a terminal (K1) is integrally formed, the second terminal and the second terminal accommodating wireless device is a terminal (K2) integrally, the terminal K1 is a first wireless communication Claim 2 or Claims configured to communicate with said terminal K2 via a path, a first wireless transceiver, a first communication line, a communication path, a second communication line, a second wireless transceiver, and a second wireless communication path A terminal-to-terminal communication connection control method using the IP transmission network described in item 3. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

Images