JP2010273174A - Time division direction control transmission device, transmission system, and time division direction control transmission method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a time division direction control transmission device, system and method, which actualizes a transmission system to connect two terminals using one line of a digital line by a TCM transmission system. <P>SOLUTION: A time division direction control transmission device 10 is equipped with: an NT interface means 11 of the digital line side; a selecting means 12 which performs switching to either of B1 and B2 channel, by being connected to a common contact point side thereof; a V24 interface conversion means 13 connected to the B1 channel side and V24 interface means 14; and an LT interface conversion means 15 connected to the B2 channel side. The transmission system is configured by using two sets of time division direction control transmission devices 10. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a time division direction control transmission apparatus, a transmission system, and a time division direction control transmission method, and more particularly to a time division direction control transmission apparatus, a transmission system, and a time division using a digital line using a time division direction control transmission method. The present invention relates to a direction control transmission method.

  The time-division direction control transmission (TCM) method is a so-called ping-pong transmission method, and is typically a transmission method used in ISDN (Integrated Services Digital Network). In this TCM system, the direction of a signal flowing in a certain time zone is controlled to be reversed in the next time zone, and this is repeated. This TCM system uses a pair of twisted pair cables (Twisted pair cable) as a transmission line and switches the direction of signal flow, so that the total duplex flows through four metallic cables (4-wire type). The data communication of the equation is made possible by the two-wire method.

  In this specification, a digital line using the TCM system is referred to as an SD line. Consider a transmission apparatus connected to an SD line and terminating the TCM system.

  FIG. 12 shows a main part of the first related technique (see, for example, Patent Document 1) of the present invention as such a transmission system. As shown in the figure, for example, an SD line 101 typified by an ISDN line has its B1 channel and B2 channel connected to a DSU (Digital Service Unit) 103 as a subscriber line terminator in the base station 102. One end of a B1 channel cable 104 is connected to the S point terminal as a digital port of the DSU 103, and a first circuit terminating device (DCE; Data Circuit-terminating Equipment) 105 is connected to the other end of the cable 104. It is connected. The first line terminator 105 includes a first V.P. A 24 interface (INF) terminal 106 is connected. Here, “V.24” is a physical layer interface standard defined by ITU-T (International Telecommunication Union Telecommunication Standardization Sector). In “V.24”, an interconnection circuit is defined between a terminal device (DTE) and a line terminator (DCE). The first line terminating device 105 is, for example, a modem (modem / demodulator). The 24-interface terminal 106 is a personal computer connected to this modem.

  The DSU 103 has a T point terminal in addition to the S point terminal. Therefore, the first V.V. In addition to the 24 interface terminal 106, the second V.V. If the 24-interface terminal 107 is also to be connected to the SD line 101, a B2 channel cable 108 having one end connected to the T point terminal is prepared. Then, the other end of the B2 channel cable 108 is connected to the second line terminator 109, and the second V.V. The 24-interface terminal 107 may be connected to the second line termination device 109.

However, in this case, as a characteristic of the S point terminal and T point terminal, there is a problem that the length L ₁ of the B2-channel cable 108 must be within 500 meters. As an example, it is assumed that the location where the DSU 103 in the base station 102 is installed and the electronic computer room where the second line termination device 109 is installed are separated by 500 mails or more. In this case, the second V.V. The computer as the 24-interface terminal 107 cannot communicate with a device (not shown) via the SD line 101.

  FIG. 13 shows a second related technique of the present invention that solves the above problems. In this communication system 120, a case where two systems of signals are transmitted between the first base station 121 and the second base station 122 is handled. In the first base station 121, the first and second V.V. 24 interface (INF) terminals 123 and 124 are installed, and are connected to corresponding first or second circuit terminators (DCE) 127 and 128 by B1 channel cables 125 and 126, respectively. In the second base station 122, the third and fourth V.P. 24 interface (INF) terminals 131 and 132 are installed, and are connected to corresponding third or fourth circuit terminators (DCE) 135 and 136 by B1 channel cables 133 and 134, respectively.

  In the second related technique, a second SD line 138 is prepared in addition to the first SD line 137. The first SD line 137 connects the first line terminator 127 and the third line terminator 135 with the B1 channel. The added second SD line 138 connects the second line terminator 128 and the fourth line terminator 136 with the B1 channel in the same manner.

  In the second related technique, the third V.D. When there is a terminal to be connected to the line other than the 24-interface terminal 131, the fourth V.V. A second SD line 138 corresponding to the one-to-one correspondence is prepared for the 24-interface terminal 132. In other words, in the second related technique, one transmission / reception side terminal is associated with the SD lines 137 and 138 on a one-to-one basis, thereby eliminating the restriction on the transmission distance.

JP 10-023001 (paragraph 0018, FIG. 1)

  However, when the second related technique is adopted, two SD lines are required when there are two communication terminals in one base station. Therefore, there is a problem that not only the cost required for constructing the communication system increases, but also the installation work becomes complicated.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a time-division direction control transmission apparatus, a transmission system, and a time division that realize a transmission system that can connect two terminals using one SD line as a digital line by the TCM transmission method. A division direction control transmission method is provided.

  In the present invention, (a) NT (Network Termination) interface means for connecting one end to a digital line using a time division direction control transmission (TCM; Time Compression Modulation) system, and (b) first and second terminals A third terminal selectively connected to any one of these terminals, the selecting means in which the third terminal is connected to the NT interface means, and (c) the selecting means Connected to the first terminal and transmitted through a digital line using the time-division direction control transmission method described above, and the V.V. defined by ITU-T (International Telecommunication Union Telecommunication Standardization Sector). V. Performs mutual conversion with data for communication terminals having 24 interfaces. 24 interface conversion means; 24 interface conversion means and V. V. Connecting a communication terminal having 24 interfaces 24 interface means, and (e) data connected to the second terminal of the selection means described above and transmitted through a digital line using the time-division direction control transmission method, and the frame format of the line termination side The time division direction control transmission device includes LT (Line Termination) interface conversion means for performing mutual conversion with data.

  According to the present invention, (a) a time-division direction control transmission apparatus according to claim 1, A first communication unit for connecting the first communication terminal to the 24 interface means via a bus and transmitting data to the first communication terminal through the B1 channel, and (b) time division according to claim 1 A direction control transmission device, the V. A second communication unit for connecting data to the B2 channel by connecting the second communication terminal to the 24 interface means via a bus; (c) the LT interface conversion means of the first communication unit described above; The transmission system includes a metallic cable for connecting the NT interface means of the communication unit.

  The present invention further comprises (a) a first communication unit comprising the time-division direction control transmission device according to claim 1 and prohibiting transmission / reception of data of the B1 channel, and (b) a time according to claim 1. A split direction control transmission apparatus, the V. A second communication unit for transmitting data through the B1 channel by bus-connecting a predetermined communication terminal to the 24 interface means; (c) the LT interface conversion means of the first communication unit described above and the second communication described above. The transmission system comprises a metallic cable connecting the NT interface means of the unit for B1 channel data transmission.

  Furthermore, in the present invention, (a) a channel selection step of selecting either B1 channel data or B2 channel data sent from a digital line using a time division direction control transmission (TCM; Time Compression Modulation) system. (B) The data of the channel selected in this channel selection step is converted into the V.C standard defined by ITU-T (International Telecommunication Union Telecommunication Standardization Sector). V. Conversion to data for communication terminals having 24 interfaces. 24 interface conversion step; The data after the conversion in the 24 interface conversion step is used as the V.S. V. Sending to a communication terminal having 24 interfaces. The time-division direction control transmission method includes a 24-interface terminal transmission step and (d) an LT interface conversion step for reconstructing the data of the channel selected in the channel selection step into the frame format data on the line termination side.

  As described above, according to the time-division direction control transmission apparatus and the time-division direction control transmission method of the present invention, by using this apparatus for a digital line using the time-division direction control transmission method, A 24-interface terminal can be easily bus-connected. Further, by using two sets of this time division direction control transmission apparatus, it is possible to use one SD line as a digital line by the TCM transmission system, Two sets of 24 interface terminals can be used. The cable length between the 24-interface terminal and the digital line can be sufficiently extended.

  Furthermore, according to the transmission system of the present invention, one SD line as a digital line by the TCM transmission system is used, Two sets of 24 interface terminals can be used. The cable length between the 24-interface terminal and the digital line can be sufficiently extended.

It is a claim corresponding | compatible figure of the time division direction control transmission apparatus of this invention. It is a claim corresponding figure of the transmission system of the present invention. It is a claim corresponding | compatible figure of the other transmission system of this invention. It is a claim corresponding | compatible figure of the time division direction control transmission method of this invention. 1 is a system configuration diagram showing a configuration of a transmission system according to an embodiment of the present invention. It is a block diagram showing concretely the composition of the 1-1st communication unit arranged in the 1st base station in this embodiment. It is the block diagram which showed the connection state of the 1-1 communication unit in a 1st base station, and the 1-2 communication unit in this Embodiment. It is explanatory drawing showing the frame structure of the signal transmitted to the LT interface part of the 1-1 communication unit from the network termination apparatus interface part of the 1-2 communication unit in this Embodiment. It is explanatory drawing showing the frame structure of the signal transmitted to the network termination apparatus interface part of the 1-2 communication unit from the LT interface part of the 1-1 communication unit in this Embodiment. It is a system block diagram showing the principal part of the transmission system in the 1st modification of this invention. It is a system block diagram showing the principal part of the transmission system in the 2nd modification of this invention. It is the system configuration figure showing the principal part about the transmission system by the 1st related art of the present invention. It is the system block diagram which showed the transmission system by the 2nd related technique of this invention.

  FIG. 1 shows a claim correspondence diagram of the time division direction control transmission apparatus of the present invention. The time division direction control transmission apparatus 10 of the present invention includes an NT interface means 11, a selection means 12, 24 interface conversion means 13; 24 interface means 14 and LT interface conversion means 15 are provided. Here, the NT interface means 11 is connected at one end to a digital line using a time division direction control transmission system. The selection unit 12 includes first and second terminals and a third terminal that is selectively connected to one of these terminals, and the third terminal is connected to the NT interface unit 11. V. The 24 interface conversion unit 13 is connected to the first terminal of the selection unit 12 and transmits data transmitted through a digital line using a time-division direction control transmission method, and V.V. Mutual conversion with data for communication terminals having 24 interfaces is performed. V. 24 interface means 14 is connected to 24 interface conversion means 13 and V.16. A communication terminal having 24 interfaces is connected. The LT interface conversion means 15 is connected to the second terminal of the selection means 12 and performs mutual conversion between data transmitted through a digital line using a time division direction control transmission method and frame format data on the line termination side. Do.

  FIG. 2 shows a claim correspondence diagram of the transmission system of the present invention. The transmission system 20 of the present invention includes a first communication unit 21, a second communication unit 22, and a metallic cable 23. Here, the first communication unit 21 is the time-division direction control transmission device according to claim 1, wherein the V.V. The first communication terminal is bus-connected to the 24 interface means, and data is transmitted through the B1 channel to the first communication terminal. The second communication unit 22 is also a time-division direction control transmission device according to claim 1, which is the same as that of claim 1. The second communication terminal is connected to the 24 interface means by a bus to transmit data using the B2 channel. The metallic cable 23 connects the LT interface conversion means of the first communication unit 21 and the NT interface means of the second communication unit.

  FIG. 3 shows a claim correspondence diagram of another transmission system of the present invention. Another transmission system 30 of the present invention includes a first communication unit 31, a second communication unit 32, and a metallic cable 33. Here, the first communication unit 31 includes the time-division direction control transmission device according to claim 1 of the claims, and prohibits data transmission / reception of the B1 channel. The second communication unit 32 is also a time-division direction control transmission device according to claim 1, which is the same as that of claim 1. A predetermined communication terminal is bus-connected to the 24 interface means, and data is transmitted through the B1 channel. The metallic cable 33 connects the LT interface conversion means of the first communication unit 31 and the NT interface means of the second communication unit 32 for B1 channel data transmission.

  FIG. 4 shows a claim correspondence diagram of the time division direction control transmission method of the present invention. The time division direction control transmission method 40 of the present invention includes a channel selection step 41, V. 24 interface conversion step 42; A 24-interface terminal transmission step 43 and an LT interface conversion step 44 are provided. Here, in the channel selection step 41, either B1 channel data or B2 channel data sent from the digital line using the time division direction control transmission system is selected. V. In the conversion step 42 for 24 interfaces, the data of the channel selected in the channel selection step 41 is converted to the V.24 standard defined by ITU-T. The data is converted into data for a communication terminal having 24 interfaces. V. In 24 interface terminal sending step 43, V. The data after the conversion by the conversion step 42 for the 24 interface is converted into V.24. It is sent to a communication terminal having 24 interfaces. In the LT interface conversion step 44, the data of the channel selected in the channel selection step 43 is reconstructed into frame format data on the line termination side.

  <Embodiment of the Invention>

  Next, an embodiment of the present invention will be described.

FIG. 5 shows the configuration of the transmission system according to the embodiment of the present invention. The transmission system 200 according to the present embodiment has a configuration in which a first base station 201 and a second base station 202 are connected by an SD line 203 made up of a pair of twisted pair cables. Here, in the first base station 201, the 1-1 V.I. 24 interface (INF) terminal 211 and 1-2 V. A 24-interface terminal 212 is arranged. 1-1. The 24-interface terminal 211 is connected to the 1-1 communication unit 214 by a cable 213 ₁ used for the B1 channel. 1-2. The 24-interface terminal 212 is connected to the 1-2 communication unit 215 by a cable 213 ₂ . A cable 216 used for the B2 channel is connected between the 1-2 communication unit 215 and the 1-1 communication unit 214. One end side of the SD line 203 is connected to the 1-1st communication unit 214.

On the other hand, in the second base station 202, the 2-1 V.V. 24 interface terminal 221 and the 2-2 V.V. A 24-interface terminal 222 is arranged. 2-1. The 24-interface terminal 221 is connected to the 2-1 communication unit 224 by a cable 223 ₁ used for the B1 channel. 2-2. 24 interface terminal 222 is connected to the communication unit 225 of the 2-2 by the cable 223 _2. A cable 226 used for the B2 channel is connected between the 2-2 communication unit 225 and the 2-1 communication unit 224. The other end side of the SD line 203 is connected to the 2-1 communication unit 224. Note that the SD line 203 of the present embodiment uses a 128 kbps (kilobits / second) digital leased line service.

  FIG. 6 specifically shows the configuration of the 1-1 communication unit arranged in the first base station. The 1-2 communication unit 215, the 2-1 communication unit 224, and the 2-2 communication unit 225 shown in FIG. 5 have the same configuration as the 1-1 communication unit 214. For this reason, illustration and description of specific configurations of the 1-2 communication unit 215, the 2-1 communication unit 224, and the 2-2 communication unit 225 are omitted.

  The 1-1 communication unit 214 has a network termination unit (NT) interface unit 233 that uses the L1 terminal 231 and the L2 terminal 232 for connecting the twisted pair cable constituting the SD line 203 shown in FIG. is doing. The network termination device interface unit 233 performs termination processing of signals transmitted through the SD line 203 by the TCM transmission method.

  The local line side of the network terminating device interface unit 233 is connected to the B1 / B2 selector 234. B1 and B2 selector 234 includes a data selection information output unit 235, a V.B. 24 interface converter 236 and LT (Line Termination) interface converter 237. The B1 / B2 selector 234 inputs data selection information 238 output from the data selection information output unit 235. In response to the data selection information 238, the B1 / B2 selector 234 sets the B1 or B2 channel in the SD line 203 to V.B. It is connected to either the 24 interface conversion unit 236 or the LT interface conversion unit 237.

V. The 24 interface conversion unit 236 receives the V.24 interface conversion unit 236. 24 interface unit 239 is connected. V. The 24 interface unit 239 is connected to the _first V.1 interface shown in FIG. 24 interface terminal 211 is connected. The LT interface conversion unit 237 is connected to an LT interface unit 241 having a function as an intra-office subscriber line termination unit (OCU (Office Channel Unit)). The LT interface unit 241 is connected to the first-second communication unit 215 via the cable 217 ₁ and the cable 216 shown in FIG.

  V. The 24 interface unit 239 determines the data speed of the signal received from the network terminating device interface unit 233 by referring to the 1-1 V.1 shown in FIG. The data is converted into the data speed required by the 24-interface terminal 211. V. The 24 interface unit 239 has a first V.1. Control signals such as CS (transmittable) and CD (data channel reception carrier detection) required by the 24-interface terminal 211 are also controlled. V. The 24 interface unit 239 has a first V.1. The voltage level for connection with the 24-interface terminal 211 is also converted. The LT interface conversion unit 237 reconstructs the channel data selected by the B1 / B2 selector 234 into the LT side frame format. The LT interface unit 241 performs termination processing of signals transmitted by the TCM transmission method with the configuration of the LT side frame.

  In the transmission system 200 of the present embodiment, the first base station 201 and the second base station 202 communicate with each other by the TCM method using the SD line 203 typified by an ISDN line. At this time, communication is performed between the first base station 201 and the second base station 202 in such a manner that the B1 channel and the B2 channel are alternately switched by so-called ping-pong transmission.

  Here, the first V.1-1 shown in FIG. Only the 24-interface terminal 211 is arranged, and the V.1-2. It is assumed that the 24-interface terminal 212 is not yet arranged. At this time, in the second base station 202, the 2nd-1 V.V. Only the 24-interface terminal 221 is arranged. It is assumed that the 24-interface terminal 222 has not been arranged yet.

  In the case of this initial arrangement structure, the 1-2 communication unit 215 is not yet connected to the 1-1 communication unit 214 in the first base station 201. Similarly, the 2-2 communication unit 225 is not yet connected to the 2-1 communication unit 224 in the second base station 202. In this situation, the B1 / B2 selector 234 that has received the data selection information 238 shown in FIG. The data is transmitted / received via the 24-interface converter 236 and the B2 channel data is transmitted / received via the LT interface converter 237.

  As the next step, the first base station 201 receives the first V.1-2 V.S. 24 interface terminal 212 is additionally arranged, and the second base station 202 receives the 2-2 V.V. Assume that a 24-interface terminal 222 is additionally arranged. These 1-2 V.V. 24 interface terminal 212 and 2-2 V. In order to ensure the communication of the 24-interface terminal 222, the system administrator prepares the 1-2 communication unit 215 and the 2-2 communication unit 225 shown in FIG.

  FIG. 7 shows the connection state of the 1-1 communication unit and the 1-2 communication unit in the first base station. Since the connection of the 2-1 communication unit 224 and the 2-2 communication unit 225 in the second base station 202 in FIG. 5 is similarly performed, the illustration thereof is omitted. This will be described with reference to FIG.

The first base station 201 receives the first V.1. When the 24-interface terminal 212 is additionally arranged, the cables 216 ₁ , 216 ₂ are connected between the LT interface unit 241 of the 1-1 communication unit 214 and the network terminating device interface unit 233 of the 1-2 communication unit 215. To do. Here, for the cables 216 ₁ and 216 ₂ , for example, metallic cables are used.

  In addition, 1-1 of V.1-1. 24 interface terminal 211 and the V-1 of the first communication unit 214. Similarly to the connection relationship of the 24 interface section 239, the V.1-2. The 24-interface terminal 212 is connected to the V.V. 24 interface unit 239 is connected. At this time, V.1-2. 24 interface terminal 212 is connected to the V.V. The 24-interface conversion unit 236 is used to set to transmit / receive B2 channel data to / from the 1-1 communication unit 214. That is, the B1 / B2 selector 234 of the first-second communication unit 215 receives the V.B. Information for selecting the 24-interface conversion unit 236 is input.

  Similarly, the 2-2 V.V. added to the second base station 202 shown in FIG. The 24-interface terminal 222 uses the 2-2 communication unit 225 to set to transmit / receive B2 channel data to / from the 2-1 communication unit 224.

  The setting of the B1 / B2 selector 234 of the 1-1 communication unit 214 in the first base station 201 is such that the 1-2 communication unit 215 is connected to the 1-1 communication unit 214. But it doesn't change. That is, the B1 / B2 selector 234 of the 1-1st communication unit 214 converts the B1 channel data into the V.B. It is set to transmit / receive via the 24-interface converter 236 and transmit / receive B2 channel data via the LT interface converter 237. Similarly, the setting of the B1 / B2 selector 234 of the 2-1 communication unit 224 in the second base station 202 is such that the 2-2 communication unit 225 is connected to the 2-1 communication unit 224. It is not changed even in the state. That is, the B1 / B2 selector 234 of the 2-1st communication unit 224 converts the B1 channel data into the V.B. It is set to transmit / receive via the 24-interface converter 236 and transmit / receive B2 channel data via the LT interface converter 237.

  With the connection as described above, in the present embodiment, the first V.1. 24 interface terminal 211 and 2-1 V.24. The 24-interface terminal 221 performs communication. In addition, using the time zone of the B2 channel of the SD line 203, the first V.1-2. 24 interface terminal 212 and 2-2 V. The 24-interface terminal 222 performs communication.

  Further, according to the present embodiment, it is possible to connect the bus on the SD line 203 in the transmission apparatus terminated with the TCM interface. Specifically, using a signal line of RS (Request to Send), SD (Send Data), RD (Receive Data), CD (Carrier Detect), CS (Clear to Send), V. Data is transmitted to and received from the 24-interface terminals 211 and 212.

  FIG. 8 shows a frame configuration of a signal transmitted from the network terminating device interface unit of the 1-2 communication unit in FIG. 7 to the LT interface unit of the 1-1 communication unit. FIG. 9 shows the frame structure of a signal transmitted from the LT interface unit of the 1-1 communication unit to the network terminating device interface unit of the 1-2 communication unit.

A frame 251 of a signal transmitted through the cable 216 ₁ shown in FIG. 7 is generally the same as a frame used when a signal is sent from a DSU (subscriber line terminating device) to an LT (line terminating circuit). Here, the communication frame word 252 is “1000000M”, and “1” and “0” are repeated for each frame.

  The CL channel 253 in the frame 251 includes various control signals and loopback signals. Here, “F1” to “F4” are 4 multiframe bits. “Q1” to “Q4” are spare bits on the T point. “ID” and “ID2” are DSU identification bits. “K1” to “K12” are CRC-12 check bits. “T1” to “T3” are a loopback 2 (B1ch) operating display bit, a loopback 2 (B2ch) operating display bit, and a loopback 2 (Dch) operating display bit, respectively. “TC1” and “TC2” are a display bit during loopback C (B1ch) operation and a display bit during loopback C (B2ch) operation, respectively. “FB” is a CRC check result display bit.

  One frame in the frame 251 includes a total of 20 slots (2B + 1) 254 from “slot 1” to “slot 20”. The content of one slot is “BBBBBBBBBDBBBBBBBBD” as shown in the figure, and the B channel includes one octet for two channels and the D channel of 1/4 octet.

A frame 261 of a signal transmitted through the cable 216 ₂ shown in FIG. 7 is generally the same as a frame used when a signal is transmitted from the LT to the DSU. Here, the communication frame word 262 is “100000M0”, and “1” and “0” are repeated for each frame.

  The CL channel 263 in the frame 261 includes various control signals and loopback signals. Description of the signals shown in FIG. 8 is omitted. “AR” is a home device interface activation command bit. “DR” is a home device interface stop command bit. “AP” is a signal device ready indication bit. “H1” to “H3” are a loopback 2 (B1ch) test command bit, a loopback 2 (B2ch) test command bit, and a loopback 2 (Dch) test command bit, respectively. “C1” and “C2” are a loopback C (B1ch) test command bit and a loopback C (B2ch) test command bit, respectively. “S” is a spare bit on the T point.

  One frame in the frame 261 includes a total of 20 slots (2B + 1) 264 from “slot 1” to “slot 20”. The content of one slot is “BBBBBBBBBDBBBBBBBBD” as shown in the figure, and the B channel includes one octet for two channels and the D channel of 1/4 octet.

  The bit rate of each frame 251 (FIG. 8) and frame 261 (FIG. 9) is, for example, 320 kilobits / second, and the transmission capacity is 64 kilobits / second for the B1 channel and B2 channel, respectively, and 14 kilobits for the D channel. / Sec. The frame words 252 (FIG. 8) and 262 (FIG. 9) and the CL channels 253 (FIG. 8) and 263 (FIG. 9) each have 8 bits. Each of the slots 1 to 20 is composed of 18 bits, and each of the parity bits (P) 255 (FIG. 8) and 265 (FIG. 9) is composed of 1 bit.

  According to the present embodiment described above, the bus connection can be easily made in the transmission apparatus terminated by the TCM interface as shown in FIG. For this reason, when extending the transmission system using the 2nd related technique of this invention shown in FIG. 13, it is not necessary to lay a new line | wire. As a result, the cost for employing the transmission system of the present embodiment can be suppressed.

  <First Modification of Invention>

  FIG. 10 shows the main part of the transmission system in the first modification of the present invention. In FIG. 10, the same parts as those in FIG. 5 are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

In the transmission system according to the first related technology described with reference to FIG. The 24-interface terminal 107 is once connected to the second line termination device 109 formed of a device such as a terminal adapter, and then connected to the S / T point of the DSU 103. On the other hand, in the transmission system 200A of the first modified example, a pair of local lines connecting the 1-1 communication unit 214 and the 1-2 communication unit 215 in the first base station 201A are paired. using cable 216 ₁ a, 216 ₂ a. These cables 216 ₁ A and 216 ₂ A are both wire wires (metallic cables) having a diameter (Φ) of 0.9 mm.

In general, by using a pair of cables 216 ₁ A and 216 ₂ A having a larger diameter, DC impedance and AC loss per unit distance are reduced. Accordingly, 216 ₁ A and 216 ₂ A having a diameter (Φ) of 0.9 millimeters for transmission of the B2 channel indicated by the distance L ₂ between the 1-1 communication unit 214 and the 1-2 communication unit 215. By using, communication of up to about 9 kilometers becomes possible. Moreover, the 1-2. The bus connection of the 24-interface terminal 212 becomes possible. Naturally, the use of the cables 216 ₁ A and 216 ₂ A having larger diameters is advantageous for data transmission over a longer distance.
<Second Modification of Invention>

  FIG. 11 shows the main part of the transmission system in the second modified example of the present invention. In FIG. 11, the same parts as those in FIG. 5 are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

  In general, while an electrical signal travels through a cable, its waveform is distorted by noise and attenuation. If the transmission distance is long and the distortion becomes severe, the receiving terminal cannot restore the electrical signal normally. Therefore, in the second modification of the present invention, the intra-office subscriber line termination unit (OCU) 301 and the 1-2 V.V. A method for maximizing the transmission distance between the 24-interface terminals 212 is provided. In the transmission system 200B of this modification, the 1-1 communication unit 214 and the 1-2 communication unit 215 are connected by the B1 channel transmission cable 302 in the first base station 201B. Instead, the 1-1 communication unit 214 and the 1-1 V.I. The connection of the 24-interface terminal 211 is in a disconnected state 303.

  In the case of this example, in the 1-1 communication unit 214 shown in FIG. 7, the B1 / B2 selector 234 is such that the data selection information 238 output from the data selection information output unit 235 always selects the B1 channel. To control. Similarly, in the 1-2 communication unit 215 shown in FIG. 7, the B1 / B2 selector 234 is controlled so that the data selection information 238 output from the data selection information output unit 235 always selects the B1 channel. Will do.

In the second modified example having such a configuration, the length L ₃ of the cable 302 connecting the 1-1 communication unit 214 and the 1-2 communication unit 215 is 50 dB (decibel) at 160 KHz (kilohertz). Can be up to a length that causes the signal attenuation. Further, the length L ₄ of the SD line 203 between the intra-site subscriber line terminating device 301 and the 1-1 communication unit 214 is the installation limit distance. Therefore, the intra-station subscriber line terminating device 301 and the 1-2 V.V. The transmission distance between the 24-interface terminals 212 can be extended by the length L ₃ from the 1-1 communication unit 214 by using the 1-2 communication unit 215.

  In the above-described embodiment and its modifications, the B1 / B2 selector 234 uses the data selection information output unit 235 to generate the V.B. The switching between the 24 interface conversion unit 236 and the LT interface conversion unit 237 is performed. The present invention is not limited to this. For example, instead of the B1 / B2 selector 234, V.B. A manual switch for selecting one of the 24 interface conversion unit 236 and the LT interface conversion unit 237 may be provided. Further, the network termination device interface unit 233 and the V.S. The 24 interface conversion unit 236 or the LT interface conversion unit 237 may be configured to be connected by an electric wire such as a jumper wire.

10 Time Division Direction Control Transmission Device 11 NT Interface Means 12 Selection Means 13 V. 24 interface conversion means 14V. 24 interface means 15 LT interface conversion means 20, 30, 200, 200A, 200B Transmission system 21, 31 First communication unit 22, 32 Second communication unit 23, 33 Metallic cable 40 Time division direction control transmission method 41 Channel selection Step 42 24 interface conversion step 43 24 interface terminal transmission step 44 LT interface conversion step 201 first base station 202 second base station 203 SD line 211 1-1. 24 interface terminal 212 V 1-2. 24 interface terminal 213 ₁ , 213 ₂ , 216 ₁ , 216 ₂ , 217 ₁ , 217 ₂ , 223 ₁ , 223 ₂ , 302 cable 214 first 1-1 communication unit 215 first 1-2 communication unit 221 second 2-1 V. 24 interface terminal 222 V2-2. 24 interface terminal 224 2-1 communication unit 225 2-2 communication unit 233 network terminator interface unit 234 B1 / B2 selector 235 data selection information output unit 236 24 interface converter 237 LT interface converter 239 24 interface unit 241 LT interface unit 301 Intra-station subscriber line termination device

Claims (9)

NT (Network Termination) interface means for connecting one end to a digital line using a time division direction control transmission (TCM; Time Compression Modulation) system;
Selection means comprising a first terminal and a second terminal and a third terminal selectively connected to one of these terminals, wherein the third terminal is connected to the NT interface means;
The data connected to the first terminal of the selection means and transmitted through the digital line using the time division direction control transmission system and the V24 interface defined by ITU-T (International Telecommunication Union Telecommunication Standardization Sector) V24 interface conversion means for performing mutual conversion with data for a communication terminal having
V24 interface means for connecting the V24 interface conversion means and the communication terminal having the V24 interface;
An LT (Line Termination) which is connected to the second terminal of the selection means and performs mutual conversion between data transmitted on a digital line using the time division direction control transmission method and frame format data on the line termination side. And a time-division direction control transmission device comprising an interface conversion means.   2. The time division direction control transmission apparatus according to claim 1, wherein the digital line is an ISDN (Integrated Services Digital Network) line, and the NT interface means has a function as a DSU (Digital Service Unit).   The LT interface converting means is a data speed / voltage level converting means for converting data received by the NT interface means into a data speed and a voltage level required by a communication terminal having the V24 interface. Item 2. A time-division direction control transmission device according to item 1.   2. The time division direction control transmission apparatus according to claim 1, wherein the V24 interface means is connected to a communication terminal having the V24 interface by a bus.   Data selection information output means for allocating the B1 channel and B2 channel data on the digital line to the V24 interface conversion means or the LT interface conversion means, and the data selection information output from the data selection information output means is the selection 2. A time-division direction control transmission apparatus according to claim 1, wherein the time-division direction control transmission apparatus is supplied for selection of means. 2. A time-division direction control transmission apparatus according to claim 1, wherein a first communication terminal is connected to the V24 interface means by a bus, and data is transmitted to the first communication terminal using the B1 channel. A communication unit of
The time-division direction control transmission device according to claim 1, wherein a second communication unit is connected to the V24 interface means by a bus to perform data transmission using the B2 channel;
A transmission system comprising: an LT interface conversion unit of the first communication unit; and a metallic cable connecting the NT interface unit of the second communication unit. A first communication unit comprising the time-division direction control transmission device according to claim 1 and prohibiting transmission and reception of data of the B1 channel;
The time-division direction control transmission device according to claim 1, wherein a second communication unit for transmitting data through the B1 channel by connecting a predetermined communication terminal to the V24 interface means via a bus;
A transmission system comprising: an LT interface conversion means of the first communication unit; and a metallic cable for connecting the NT interface means of the second communication unit for B1 channel data transmission.   The transmission system according to claim 6 or 7, wherein the metallic cable has a diameter of at least 0.9 millimeters. A channel selection step of selecting either B1 channel data or B2 channel data sent from a digital line using a time division direction control transmission (TCM; Time Compression Modulation) system;
A V24 interface conversion step for converting the data of the channel selected in this channel selection step into data for a communication terminal having a V24 interface defined by ITU-T (International Telecommunication Union Telecommunication Standardization Sector);
A V24 interface terminal sending step for sending data converted by the V24 interface conversion step to a communication terminal having the V24 interface;
A time division direction control transmission method comprising: an LT interface conversion step of reconstructing data of a channel selected in the channel selection step into frame format data on a line termination side.

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