JP4025577B2 - PHS inter-base station synchronization system, method and program thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a system in which a private branch exchange (hereinafter referred to as PBX) and a PHS base station are connected to an Ethernet LAN (registered trademark).
[0002]
[Prior art]
In PHS (Personal Handy-phone System), a 4-channel multiple multi-carrier TDMA (Time Division Multiple Access) / TDD (Time Division Access) method is adopted as a transmission method. The TDMA / TDD system is a system in which a radio frequency is time-divided, a specific time zone (time slot) is allocated to a caller, and communication is performed in the allocated slot.
[0003]
In a mobile communication system such as a PHS in which a plurality of base stations are provided and each base station transmits / receives to / from the mobile station by TDMA, the base stations are adjacent to each other unless the frame synchronization of the transmission / reception signals of the base stations is taken. Due to the transmission / reception signal from the base station, a plurality of continuous time slots are subject to interference. For this reason, the wireless channel at that timing cannot be used, and the radio wave cannot be effectively used.
[0004]
Techniques for solving such problems are disclosed in Japanese Patent Application Laid-Open No. 11-205849, “Method for Establishing Inter-Base Station Synchronization Timing and TDMA System”, and Japanese Patent Application Laid-Open No. 10-145848, “TDMA Mobile Communication Between Base Stations”. "Frame synchronization method". Hereinafter, the techniques disclosed in these publications will be described.
[0005]
Japanese Patent Laid-Open No. 11-205849 discloses "a method for establishing synchronization timing between base stations and a TDMA system". (A) a step of obtaining distance data between base stations, and (b) a step of obtaining distance data between base stations. (C) transmitting the distance data from the predetermined device to each base station; (d) transmitting the distance data from the first base station to the second base station. (E) calculating a data delay time between the first base station and the second base station based on the distance data in the second base station, (f) in the second base station, There is disclosed a method for establishing synchronization timing between base stations comprising the step of calculating an appropriate transmission timing based on the calculated delay time.
[0006]
In the “TDMA mobile communication inter-base station frame synchronization method” disclosed in Japanese Patent Laid-Open No. 10-145848, there is a hierarchical relationship in which a predetermined base station is a reference station which is the highest layer in a base station group to be subjected to frame synchronization. Each base station has a base station at the next higher level as a regular monitoring destination base station, and the frame timing of the regular monitoring destination base station and its own station are set at every predetermined regular monitoring cycle. A frame synchronization process that compares the frame timing with the frame timing of its own station to the frame timing of the periodic monitoring destination base station when it is determined whether or not the frame synchronization process is necessary. A TDMA mobile communication base station frame synchronization method for performing TDMA mobile communication, wherein a base station of a TDMA mobile communication in which a periodic monitoring period is set shorter as a base station in a higher hierarchy During frame synchronization method is disclosed.
[0007]
An example of a system that arranges base stations on the Internet is disclosed in Japanese Patent Laid-Open No. 2002-33697. In the data transmission system using a network having a line connecting a plurality of radio base stations and a line connecting the radio base station and the mobile terminal, the technology disclosed in this publication is a mobile terminal in the radio base station area. From the mobile terminal, when communicating the first data through the radio base station, the mobile terminal adds an identifier representing the multiplexing of the data to the first data to be transmitted and transmits it to the radio base station. When transmitting the second data to the other terminal through the radio base station, the mobile terminal adds an identifier representing the multiplexing of the data to the second data to be transmitted. The data is mixed and transmitted to the radio base station, and the radio base station separates the received data according to the identifier and sends it to each terminal. Thus, by adding an identifier to data between the radio base station and the mobile terminal, it becomes possible to identify multiple data, and conventionally, only one line can be established between the radio base station and the mobile terminal. Compared to conventional systems, it can receive data from different sources at the same time and send data from different destinations at the same time.
[0008]
[Problems to be solved by the invention]
However, when the PBX and the PHS base station are connected by an Ethernet LAN, the following problems occur.
[0009]
Between the PHS base stations connected to the circuit switching-based ISDN interface, the synchronization signal supplied from the PBX 10 could be supplied to each PHS base station via the ISDN line. This is the physical layer interface of ISDN, I.I. This is because the transmission speed and transmission line code conditions are defined in 430. However, between the PHS base stations connected to the Ethernet LAN, since the Ethernet LAN is a best effort line whose bandwidth is not guaranteed, a synchronization signal from the PBX cannot be supplied to each PHS base station. For this reason, in the PHS employing the TDMA method, interference of TDMA frames occurs, and there is a problem that wireless radio waves cannot be effectively used.
[0010]
Further, as described above, the Ethernet LAN that connects the PHS between the PHS base stations is a best effort line with no guaranteed bandwidth, and therefore, it is assumed that a data packet delay occurs due to temporary congestion of the line. For this reason, retransmission control, which is a feature of PIAFS, frequently occurs due to data delay and data loss in the Ethernet LAN, and the original communication speed cannot be secured.
[0011]
The present invention has been made in view of the above circumstances, and provides a synchronization system between PHS base stations, a method thereof, and a program capable of eliminating problems caused by connecting between PHS base stations to an Ethernet LAN. Objective.
[0012]
[Means for Solving the Problems]
In order to achieve such an object, the invention described in claim 1 is a system in which a private branch exchange apparatus and a plurality of PHS base stations are connected via an Ethernet LAN. A private branch exchange apparatus that notifies an arbitrary one of a plurality of PHS base stations of an identification code for identifying a private PHS base station that outputs a radio wave at a predetermined timing, which is input from a maintenance console. The PHS base station that has received the notification from detects the control signal output from the designated private-use PHS base station based on the originating identification code, and generates a synchronization signal based on the received control signal. Operates as a reference station for the PHS base station group The PHS base station other than the PHS base station that has received the notification from the private branch exchange generates a synchronization signal. Operates as a reference station Detects a control signal from the PHS base station, generates a synchronization signal based on the received control signal Synchronize between PHS base stations connected to Ethernet LAN Communicate with PHS mobile terminals At the same time, in data transmission / reception between the private branch exchange and the PHS base station, the transmitting side adds an added value obtained by adding a value obtained by measuring the elapsed time from the call connection to the initial value set at the time of the call connection. As a value indicating the transmission timing of the data, it is included in the transmission frame and transmitted to the other side, and the data reception side adds the added value received via the Ethernet LAN and the elapsed time until the data is received from the call connection to the initial value. The data delay in the Ethernet LAN is determined by comparing with the added value obtained by adding the timed value. It is characterized by that.
[0013]
The invention according to claim 2 is the invention according to claim 1, wherein the PHS base station that has received the notification from the private branch exchange detects a control signal from the private PHS base station designated by the private branch exchange. If the control signal cannot be detected, a control signal from a private PHS base station connected to a public PHS base station or another private branch exchange different from the private branch exchange is detected, and synchronization is performed based on the received control signal. A signal is generated to communicate with a PHS mobile terminal.
[0014]
The invention according to claim 3 is the invention according to claim 1, wherein the PHS base station that has received the notification from the private branch exchange detects a control signal from the private PHS base station designated by the private branch exchange. If the control signal cannot be detected, a control signal from a private PHS base station connected to another private branch exchange different from the private branch exchange is detected, and a synchronization signal is generated based on the received control signal to generate a PHS. If a control signal from a private PHS base station that communicates with the mobile terminal and is connected to another switching apparatus different from the private branch exchange apparatus cannot be detected, control from the public PHS base station A signal is detected, a synchronization signal is generated based on the received control signal, and communication with the PHS mobile terminal is performed.
[0015]
The invention according to claim 4 is the invention according to claim 2, wherein the PHS base station that has received the notification from the private branch exchange is connected to a public PHS base station or another private branch exchange different from the private branch exchange. When a control signal from the private PHS base station cannot be detected, a unique clock signal is generated and communication with the PHS mobile terminal is performed.
[0016]
The invention according to claim 5 is the invention according to claim 3, in which the PHS base station that has received the notification from the private branch exchange apparatus is not able to detect the control signal from the public PHS base station. And generating a clock signal to communicate with the PHS mobile terminal.
[0017]
The invention described in claim 6 6. The invention according to claim 1, wherein when a data delay is determined to occur in the Ethernet LAN, a re-synchronization procedure for PIAFS, which is a PHS data communication protocol, is started. It is characterized by that.
[0018]
The invention described in claim 7 A synchronization method between PHS base stations in a system in which a private branch exchange apparatus and a plurality of PHS base stations are connected via an Ethernet LAN, wherein the private branch exchange apparatus has a predetermined timing from a maintenance console of the private branch exchange apparatus. A call origination identification code for identifying a private PHS base station that outputs a radio wave is input, and the input call origination identification code is notified to any one of a plurality of PHS base stations. In the PHS base station that has received the notification, a control signal output from the designated private PHS base station is detected by a call identification code, and a synchronization signal is generated based on the received control signal to generate a PHS base station group A PHS base station that operates as a reference station and generates a synchronization signal in a PHS base station other than the PHS base station that has received notification from the private branch exchange. A control signal is generated, a synchronization signal is generated based on the received control signal, communication is performed between the PHS base stations connected to the Ethernet LAN to communicate with the PHS mobile terminal, and the private branch exchange In the data transmission / reception with the PHS base station, the transmission side adds an addition value obtained by adding the value obtained by measuring the elapsed time from the call connection to the initial value set at the time of the call connection, and a value indicating the data transmission timing. The data reception side adds the addition value received via the Ethernet LAN and the value obtained by counting the elapsed time until the data is received from the call connection to the initial value. Data delay in Ethernet LAN is determined by comparing with the added value It is characterized by that.
[0019]
The invention described in claim 8 Claim 7 In the described invention, If the PHS base station that has received the notification from the private branch exchange cannot detect the control signal from the private PHS base station specified by the private branch exchange, the public PHS base station or the private branch exchange Detects a control signal from a private PHS base station connected to another private branch exchange different from the device, generates a synchronization signal based on the received control signal, and communicates with the PHS mobile terminal It is characterized by that.
[0020]
The invention according to claim 9 Claim 7 In the described invention, When the control signal from the private PHS base station designated by the private branch exchange apparatus cannot be detected in the PHS base station that has received the notification from the private branch exchange apparatus, it is different from the private branch exchange apparatus. Detects a control signal from a private PHS base station connected to the private branch exchange, generates a synchronization signal based on the received control signal, communicates with the PHS mobile terminal, and is different from the private branch exchange. If the control signal from the private PHS base station connected to the switching device cannot be detected, the control signal from the public PHS base station is detected, and a synchronization signal is generated based on the received control signal. To communicate with PHS mobile terminals It is characterized by that.
[0021]
The invention according to claim 10 is the invention according to claim 8, A PHS base station that has received a notification from the private branch exchange can detect a control signal from a private PHS base station connected to a public PHS base station or another private branch exchange different from the private branch exchange. If not, it generates its own clock signal and communicates with the PHS mobile terminal It is characterized by that.
[0022]
The invention described in claim 11 is the invention described in claim 9, When the PHS base station that has received the notification from the private branch exchange cannot detect the control signal from the public PHS base station, it independently generates a clock signal and communicates with the PHS mobile terminal. It is characterized by that.
[0023]
The invention according to claim 12 Any one of claims 7 to 11 In the described invention, When it is determined that a data delay occurs in the Ethernet LAN, the PIAFS resynchronization procedure that is a PHS data communication protocol is started. It is characterized by that.
[0024]
The invention according to claim 13 is a system in which a private branch exchange apparatus and a plurality of PHS base stations are connected via an Ethernet LAN. PHS base station synchronization program In the private branch exchange, a call identification code for identifying a private PHS base station that outputs a radio wave at a predetermined timing is input from the maintenance console of the private branch exchange, and the input call Notification of identification code to any one of multiple PHS base stations Execute the process to In the PHS base station that has received the notification from the private branch exchange, the control signal output from the designated private PHS base station is detected by the calling identification code, and the synchronization signal is generated based on the received control signal. Execute processing to operate as a reference station of the PHS base station group, In the PHS base station other than the PHS base station that has received the notification from the private branch exchange, a synchronization signal is generated. Operates as a reference station Detects a control signal from the PHS base station, generates a synchronization signal based on the received control signal Synchronize between PHS base stations connected to Ethernet LAN Communicate with PHS mobile terminals In addition to executing the process, in data transmission between the private branch exchange and the PHS base station, the transmission side adds the value obtained by measuring the elapsed time from the call connection to the initial value set at the time of the call connection The value is included in the transmission frame as a value indicating the data transmission timing and transmitted to the other side, and the data receiving side performs the addition value received via the Ethernet LAN and the initial value from the call connection to the data. The processing for determining the data delay in the Ethernet LAN is performed by comparing with the added value obtained by adding the value obtained by measuring the elapsed time until receiving It is characterized by that.
[0025]
According to a fourteenth aspect of the present invention, in the invention according to the thirteenth aspect, in the PHS base station that has received the notification from the private branch exchange apparatus, the control signal from the private PHS base station designated by the private branch exchange apparatus is detected. If the control signal cannot be detected, a control signal from a private PHS base station connected to a public PHS base station or another private branch exchange different from the private branch exchange is detected, and synchronization is performed based on the received control signal. Generate signals and communicate with PHS mobile terminals Execute the process It is characterized by that.
[0026]
According to a fifteenth aspect of the invention, in the thirteenth aspect of the invention, the PHS base station that has received the notification from the private branch exchange detects the control signal from the private PHS base station designated by the private branch exchange. If the control signal cannot be detected, a control signal from a private PHS base station connected to another private branch exchange different from the private branch exchange is detected, and a synchronization signal is generated based on the received control signal to generate a PHS. If the control signal from the private PHS base station connected to the other switching apparatus different from the private branch exchange apparatus is detected after performing the process of communicating with the mobile terminal, the public PHS base Detects a control signal from a station, generates a synchronization signal based on the received control signal, and communicates with a PHS mobile terminal Execute the process It is characterized by that.
[0027]
According to a sixteenth aspect of the present invention, in the invention of the fourteenth aspect, the PHS base station that has received the notification from the private branch exchange is connected to a public PHS base station or another private branch exchange different from the private branch exchange. If the control signal from the private PHS base station cannot be detected, it generates its own clock signal and communicates with the PHS mobile terminal Execute the process It is characterized by that.
[0028]
The invention according to claim 17 is the invention according to claim 15, in which the PHS base station that has received the notification from the private branch exchange apparatus cannot detect the control signal from the public PHS base station. To generate a clock signal and communicate with the PHS mobile terminal Execute the process It is characterized by that.
[0029]
In the invention described in claim 18, in the invention described in any one of claims 13 to 17, when it is determined that a data delay has occurred in the Ethernet LAN, the PIAFS data communication protocol of PHSFS is restored. A process for starting the synchronization procedure is executed.
[0042]
DETAILED DESCRIPTION OF THE INVENTION
DESCRIPTION OF EMBODIMENTS Next, embodiments according to the PHS base station synchronization system, method and program thereof of the present invention will be described in detail with reference to the accompanying drawings. Referring to FIG. 1 to FIG. 8, there are shown embodiments of a PHS base station synchronization system, method and program thereof according to the present invention.
[0043]
As shown in FIG. 1, in this embodiment, a private branch exchange (hereinafter referred to as PBX) 10 and a PHS base station 20 (in this embodiment, 20A, 20B, and 20C) are connected. (Not limited to this) is connected to the Ethernet LAN (A). Further, in this system, PHS mobile terminals (hereinafter referred to as PS) 30 that communicate with the PHS base station 20 (in this embodiment, PHS mobile terminals 30A, 30B, and 30C are included in the PHS base stations 20A, 20B, and 20C). Are connected to each other, but the connection form is not limited to this), and personal computers 31, 32, and 33 are connected to the PS 30. Further, a dial-up router 34 equipped with a PPP (Point-to-Point Protocol) protocol is connected to the circuit-switching-based ISDN interface of the PBX 10, and a circuit-switching-based terminal (in this embodiment, the PHS mobile terminal 30). And the server 35 connected to the Ethernet LAN (B) are relayed.
[0044]
Next, the PHS signal conversion unit 100 of the PBX 10 will be described with reference to FIG.
The PHS signal conversion unit 100 includes call control (CC: Call Control), mobility management (MM: Mobility Management), and radio management (RT: Radio Transmission) defined by RCR STD-28 (Personal Handy Phone System RCR Standard). It plays the role of relaying each control information and communication information such as voice and PIAFS (PHS Internet Access Forum Standard) data.
[0045]
The PHS signal conversion unit 100 is connected to the Ethernet LAN through the LAN interface unit 120 and is connected to the internal bus of the PBX 10 through the internal bus interface unit 110. For processing of signals transferred from the internal bus toward the PHS base station 20, a reception processing unit 113, a signal determination unit 114, a PIAFS processing unit 116, a voice processing unit 117, a call control processing unit 118, UDP (User Datagram protocol). A processing unit 115 and a buffer 119 are provided. For processing of signals transferred from the PHS base station 20 toward the internal bus, the buffer 109, the UDP processing unit 105, the signal determination unit 104, the PIAFS processing unit 106, the voice processing unit 107, the call control processing unit 108, and transmission A processing unit 103 is provided.
[0046]
The Ethernet LAN is a best-effort line whose bandwidth is not guaranteed, and it is assumed that data packets are delayed due to temporary congestion of the line. Therefore, buffers 109 and 119 for absorbing this delay are prepared for both transmission and reception. When a general 64 kbps band (G.711 codec) is adopted and a signal is processed every 20 ms, one data packet is 160 bytes, so it is necessary to prepare a buffer size of 160 × n.
[0047]
The UDP processing unit 105 deletes the header part added by the PHS base station 20 and outputs it to the signal determination unit 104. Further, the UDP processing unit 115 adds a UDP header designating the other party IP address to the control information processed by the call control processing unit 118 and outputs the control information to the LAN interface unit 120 via the buffer 119. In addition, the UDP processing unit 115 is configured to use TTC (The Telecommunication Technology Committee) standard JT-H.TM. For the audio information processed by the audio processing unit 117 and the PIAFS data processed by the PIAFS processing unit 116. A header according to the 225.0 RTP (Real-Time Transport Protocol) procedure is added and output.
[0048]
The signal determination unit 104 determines whether a PHS control signal {SACCH (Slow Associated Control Channel) / FACCH (Fast Associated Control Channel)} or a communication signal {TCH (Traffic Channel)} from the signal received from the PHS base station 20. If it is a control signal for PHS, the “communication capability” for starting communication is confirmed from a call setup (SETUP) message of the control signal (SACCH / FACCH), and the corresponding call is voice or PIAFS data. Determine whether. According to this determination, the PIAFS data is output to the PIAFS processing unit 106, the audio data is output to the audio processing unit 107, and the control information is output to the call control processing unit 108. Further, the signal determination unit 114 determines whether the signal is a PHS control signal or a communication signal (TCH) from the signal received by the reception processing unit 113 via the internal bus interface 110, and is a PHS control signal. If it is, the “transfer capability” for starting communication is confirmed from the call setup (SETUP) message of the control signal (SACCH / FACCH), and it is determined whether the corresponding call is voice or PIAFS data. According to this determination, the PIAFS data is output to the PIAFS processing unit 116, the audio data is output to the audio processing unit 117, and the control information is output to the call control processing unit 118.
[0049]
The synchronization generation unit 121 generates a 5 ms synchronization signal based on the clock signal supplied from the internal bus of the PBX 10 and supplies it to the PIAFS processing units 106 and 116 and the buffers 109 and 119 that absorb the delay.
[0050]
Next, the configuration of the PHS base station will be described with reference to FIG.
The PHS base station 20 performs communication such as call control (CC), mobility management (MM), radio management (RT) control information defined by RCR STD-28, voice, PIAFS (PHS Internet Access Forum Standard) data, and the like. It plays a role in relaying information.
[0051]
The PHS base station 20 is connected to the Ethernet LAN (A) via the LAN interface unit 220. In addition, information is transmitted to and received from the PHS mobile terminal 30 via the antenna 210. A signal received by the LAN interface unit 220 via the Ethernet LAN (A) is temporarily accumulated in the buffer 209, and is then processed by a UDP processing unit 205, a signal determination unit 204, a PIAFS processing unit 206, a voice processing unit 207, and a call control process. Processing is performed by the unit 208 and transmitted from the transmission processing unit 203 to the PHS mobile terminal 30. Further, the signal transmitted from the PHS mobile terminal 30 is received by the reception processing unit 213 and processed by the signal determination unit 214, the PIAFS processing unit 216, the voice processing unit 217, the call control processing unit 218, and the UDP processing unit 215. Is done. Thereafter, the data is temporarily stored in the buffer 219 and output to the Ethernet LAN (A) by the LAN interface unit 220.
[0052]
As described above, the Ethernet LAN is a best-effort line whose bandwidth is not guaranteed, and it is assumed that data packets are delayed due to temporary congestion of the line. Therefore, the buffers 209 and 219 are prepared for both transmission and reception.
[0053]
The UDP processing unit 205 deletes the header part added by the PBX 10 and outputs it to the signal determination unit 204. Further, the UDP processing unit 215 adds a UDP header designating the other party's IP address to the control information processed by the call control processing unit 218, temporarily stores it in the buffer 219, and then outputs it to the LAN interface unit 220. In addition, the UDP processing unit 215 performs the TTC standard JT-H.3 on the audio information processed by the audio processing unit 217 and the PIAFS data processed by the PIAFS processing unit 216. A header according to the 225.0 RTP procedure is added and output.
[0054]
The signal determination unit 204 determines whether it is a control signal for PHS (SACCH / FACCH) or a communication signal (TCH) from the received signal, and if it is a control signal for PHS, the control signal (SACCH) / FACCH) call setting (SETUP) message confirms the “communication capability” for starting communication, and determines whether the corresponding call is voice or PIAFS data. In accordance with this determination, the PIAFS data is output to the PIAFS processing unit 206, the audio data is output to the audio processing unit 207, and the control information is output to the call control processing unit 208. In addition, the signal determination unit 214 determines whether the PHS control signal (SACCH / FACCH) or the communication signal (TCH) is transmitted from the signal transmitted from the PHS mobile terminal 30 via the wireless line and received by the reception processing unit 213. If it is a control signal for PHS, the “communication capability” for starting communication is confirmed from a call setup (SETUP) message of the control signal (SACCH / FACCH), and the corresponding call is voice or PIAFS data. Determine whether. In accordance with this determination, the PIAFS data is output to the PIAFS processing unit 216, the audio data is output to the audio processing unit 217, and the control information is output to the call control processing unit 218.
[0055]
The present embodiment configured as described above has an object of avoiding interference of TDMA frames by establishing synchronization between PHS base stations connected to an Ethernet LAN, as shown in FIG.
[0056]
Between the PHS base stations connected to the circuit switching-based ISDN interface, the synchronization signal supplied from the PBX 10 could be supplied to each PHS base station 20 through the ISDN line. This is the physical layer interface of ISDN, I.I. This is because the transmission speed and transmission line code conditions are defined in 430.
[0057]
However, between the PHS base stations connected to the Ethernet LAN, since the Ethernet LAN is a best effort line whose bandwidth is not guaranteed, the synchronization signal from the PBX 10 cannot be supplied to each PHS base station.
[0058]
For this reason, in the present embodiment, from the maintenance console of the PBX 10, the “calling identification code (42 bits)” of another private PHS system whose operation is known in advance (outputting radio waves at a predetermined timing) is obtained. An arbitrary PHS base station 20 in the PHS base station group connected to the PBX 10 and the Ethernet LAN (here, it is assumed that the PHS base station 20A shown in FIG. 1 is notified). The “calling identification code” is identification information that can identify a radio wave output from the base station.
[0059]
Receiving this notification, the PHS base station 20A detects a control signal (LCCH signal) output from the base station of the private PHS system specified by the call identification code and generates a synchronization signal synchronized with this control signal. , Operate as a reference station for the PHS base station group.
[0060]
If the control signal from the private PHS system designated by the PBX 10 cannot be detected, the PHS base station 20A (hereinafter referred to as a reference base station) that has received the notification from the PBX 10 operates in the vicinity. Other private PHS systems (private PHS base stations connected to other PBXs different from the PBX 10 to which the reference base station 20A is connected), or other public PHS base stations (the reference base station 20A is A control signal from a public PHS base station connected to another PBX different from the connected PBX 10 is detected, and a synchronization signal synchronized with the control signal is generated.
[0061]
In addition, when a control signal from another private PHS system or another public PHS base station cannot be detected, the reference base station 20A independently generates a synchronization signal. In addition, other PHS base stations (PHS base stations 20B and 20C shown in FIG. 1) in the same group connected to the PBX 10 via the Ethernet LAN that have not received the notification from the PBX 10 are transmitted from the reference base station 20A. The output radio wave is detected and synchronized with the reference base station 20A. Note that the “originating identification code” notified from the PBX 10 is the “originating identification code” of the own PHS base station 20A in addition to the originating identification code for identifying the private PHS system for the reference base station 20A. Is sent to other PHS base stations in the same group as the reference base station 20A (PHS base stations 20B and 20C shown in FIG. 1), only the “originating identification code” of the own PHS base station Be notified. The other PHS base stations (20B, 20C) in the same group can detect the radio wave output from the PHS base stations in the same group based on the “calling identification code” notified from the PBX 10.
[0062]
Further, as described above, the Ethernet LAN that connects the PHS base stations and the PBX 10 is a best-effort line whose bandwidth is not guaranteed. Therefore, it is assumed that data packets are delayed due to temporary congestion of the line. For this reason, the malfunction of the fall of communication speed arises.
[0063]
FIG. 4 shows the TTC standard JT-H.264 added to the PIAFS data and the voice data by the UDP processing unit 215 of the PHS base station 20 and the UDP processing unit 115 of the PBX. The structure of the header part according to the 225.0 RTP procedure is shown. As shown in FIG. 4, this header portion includes time stamp information for notifying the time at the time of data transmission. The PBX 10 and the PHS base station 20 write and transmit a value obtained by adding a value of 20 ms to the initial value at the time of call setting in the time stamp area of the header portion every time data is transmitted. The receiving side compares the time stamp value transmitted from the other side with the time stamp value at the time of data reception, and determines that a delay has occurred in the Ethernet LAN if this value is more than a predetermined threshold value. Then, the PIAFS resynchronization procedure is started. FIG. 5 shows a processing sequence during call connection. As shown in FIG. 5, when a call origination operation is performed from the PC 31, a SETUP message is notified to the router 34, and a CALL PROC (EEDING) signal indicating that the requested call setup has been started is issued from the router 34. 30, and then the PHS mobile terminal 30 is notified of a CONN (ECT) signal indicating that the call has been accepted. The PHS base station 20 that has received this CONN signal transmits a PIAFS data transmission request to the PHS mobile terminal 30, and data communication is started by transmitting PIAFS data from the PHS mobile terminal 30 that has received the request. The PIAFS resynchronization sequence is a procedure in which the PHS base station 20 that has received the CONN signal transmits a PIAFS data transmission request to the PHS mobile terminal 30 and the PIAFS data is transmitted from the PC 34 to the server 35.
[0064]
In this way, in the present embodiment, synchronization can be established even if PIAFS data communication is performed on a line in which a delay can occur, and the PIAFS resynchronization procedure can be independently performed even if the communication speed is reduced due to the delay. By starting, delay can be avoided.
[0065]
Next, the operation procedure of the reference base station that has received an instruction from the PBX 10 will be described with reference to the flowchart shown in FIG.
First, the PBX 10 inputs from the maintenance console of the PBX 10 the “calling identification code (42 bits)” of a private PHS system whose operation is known in advance (outputting radio waves at a predetermined timing). Notification is made to any one of the base station groups connected to the PBX 10 via the Ethernet LAN. The call identification code is information that can detect a radio wave transmitted from the corresponding base station. Further, it is assumed that the designated private PHS system is a system connected to a PBX different from the PBX 10.
[0066]
The PHS base station that has received the notification of the calling identification code from the PBX 10 (for convenience of explanation, the PHS base station 20A shown in FIG. 1) (step S1 / YES) is sent from the PHS base station designated by the PBX 10 The output radio control signal (LCCH: Logical Control Channel) is detected by the notified calling identification code (step S2 / YES). The detected radio control signal is input, and a 5 ms synchronization signal synchronized with the radio control signal is generated by the TDMA synchronization extraction unit 221 (step S3).
[0067]
If the radio control signal cannot be received from the PHS base station of the private PHS system instructed from the PBX 10 (step S2 / NO), the PHS base station 20A A radio control signal (LCCH signal) from the PHS base station of the PHS system for use is detected (step S4). A radio control signal is received from the detected base station of the private PHS system (step S5 / YES), and the TDMA synchronization extraction unit 221 generates a 5 ms synchronization signal synchronized with the radio control signal (step S6). Note that the base station of the private PHS system to be detected is a base station connected to a PBX different from the PHS base station 20A.
[0068]
Furthermore, when the radio control signal from the base station of the private PHS system operated in the vicinity cannot be detected (step S5 / NO), the PHS base station 20A The radio control signal (LCCH signal) from is detected. The detected radio control signal from the public PHS base station is received (step S8 / YES), and the TDMA synchronization extraction unit 221 generates a 5 ms synchronization signal synchronized with the radio control signal (step S9). It is assumed that the public PHS base station to be detected is a PHS base station connected to a PBX different from the PBX 10 to which the reference base station is connected.
[0069]
If a radio control signal from a private PHS system or a public PHS base station cannot be detected (step S8 / NO), the TDMA synchronization extraction unit 221 of the reference base station independently generates a 5 ms synchronization signal. And operates as a reference base station in the same base station group (step S10).
[0070]
In addition to the PLL reference signal, the generated synchronization signal is supplied to the PIAFS signal processes 206 and 216 and the buffers 209 and 219 for absorbing delay. The PIAFS processing units 206 and 216 output PIAFS data to the next stage circuit based on the supplied synchronization signal. The synchronization signal supplied to the buffers 209 and 219 is used as a reference signal when data is extracted from the buffers 209 and 219. When PIAFS data communication is performed in a system in which the PHS base station 20 and the PBX 10 are connected to the Ethernet LAN, data delay and data loss occur when passing through the Ethernet LAN that is an asynchronous line, and retransmission control, which is a characteristic of PIAFS Frequently occurs. Accordingly, there arises a problem that the original communication speed cannot be ensured. Therefore, by transmitting the PIAFS data and taking out the data from the buffer based on the generated 5 ms synchronization signal, it is possible to minimize retransmission control due to data delay and data loss when passing through the asynchronous Ethernet LAN. it can.
[0071]
Further, other PHS base stations connected to the same PBX 10 other than the reference base station detect the radio wave output from the reference base station based on the originating identification code of the own PHS base station notified from the PBX 10, and this Synchronize with radio waves.
[0072]
Here, it demonstrates in detail, referring the PHS frame block diagram shown by FIG.
The PHS frame structure consists of a 5 ms frame in which 8 frames of 625 μs are multiplexed. As shown in FIG. 7, 4 slots are allocated for transmission and reception, and 4 multiplexing communication is possible. Normally, one of the four slots is allocated for control, necessary information is transmitted at regular intervals, and the PHS mobile terminals 30 under the control of the PHS base station 20 are controlled.
[0073]
Specifically, as shown in FIG. 7, the first downlink slot is assigned to a control slot, and a control signal is transmitted at an interval of 5 ms × n (n = LCCH interval period). For example, if n is 30, a control signal (black slot in FIG. 7) is transmitted from the PHS base station 30 every 150 ms. Slots 2.5 ms after the slot allocated for control (the latter half of the 5 ms frame) are used as reception slots for receiving information from the PHS mobile terminal 30 that has received information from the PHS base station 20. Is done. For transmission / reception of data between one PHS base station 20 and a PHS mobile terminal 30 under the control of the PHS base station, four slots for transmission / reception are used. For the next data transmission / reception, in the embodiment shown in FIG. It must wait until the slot after 145 ms (5 × 29 ms).
[0074]
The reference base station detects a control signal output from the PHS base station designated by the PBX 10 in an interval of 145 ms where data transmission / reception is not performed with the subordinate PHS mobile terminal, and the control signal of the designated base station is 145 ms. By receiving at every interval period, a synchronization signal of 5 ms is generated.
[0075]
Further, the other PHS base stations 20 in the same group as the reference base station detect the control signal in the first downlink slot of FIG. 7 output from the reference base station, and output this signal every 150 ms from the reference base station. A control signal is received every 150 ms and synchronized with the reference base station. That is, the other PHS base stations perform data transmission / reception with subordinate PHS mobile terminals using any one of the eight slots in the 145 ms section shown in FIG.
[0076]
Next, an operation procedure when data is transmitted / received to / from the server 35 via the router 34 from the PC 31 connected to the PHS mobile terminal 30A will be described with reference to the flowchart shown in FIG.
[0077]
FIG. 5 shows a processing sequence at the time of connection. When the PHS base station 20A receives the SETUP message from the PHS mobile terminal 30A, the signal determination unit 214 determines that it is a call control signal and notifies the call control processing unit 218. Furthermore, since the transmission capability in the SETUP message is indicated as “unrestricted data” during PIAFS data communication, it is indicated by “* 2” in FIG. 5 after the call connection process indicated in FIG. 5 “* 1”. As described above, it is determined that the call is a data call, and the data after the completion of the call connection is notified to the PIAFS processing units 106, 116, 206, and 216. Specifically, a SYNC pattern (32 bits) in a synchronization frame defined by ARIB STD-T76, which is a PIAFS standard, is searched from the received bit string, and after detection, PIAFS data is transmitted in units of 640 bits. Continue processing as a thing.
[0078]
Since the information notified in one slot of PHS is 160 bits, data of (640 bits / 160 bits) × 5 mS = 20 mS is accumulated in the PAIFS processing unit 216 to generate a 1 PIAFS packet. At the time of reception, the data stored in the reception buffers 109 and 209 are extracted every 20 mS, which is a unit of 1 PIAFS packet, based on the synchronization signal, so that transmission and reception are synchronized.
[0079]
However, since the PHS base station 20 and the PBX 10 are connected to the Ethernet LAN as shown in FIG. 1, it is necessary to consider the delay in the Ethernet LAN. Therefore, TTC standard JT-H. According to the RTP data transfer protocol procedure of 225.0, the UDP processing unit 115 adds an RTP header to the PIAFS data, but 20 mS has elapsed for each frame in the time stamp (32 bits) area defined by the header shown in FIG. Insert a time to indicate This time stamp information is used as a criterion for measuring arrival jitter on the receiving side.
[0080]
Specifically, when the determination is made on the PHS base station 20 side, the PIAFS processing unit 216 for PBX 10 sets a value that is increased by 20 mS for each data transmission in the “time stamp” information that is initially set at the start of call setting (step 216). S21), comparing the time stamp value set by the PIAFS processing unit 216 with the time stamp value confirmed by the PIAFS processing unit 206 received from the PBX 10 (step S22), and the difference between these values deviates from a predetermined threshold value. In the case (step S23 / NO), it is determined that a delay has occurred in the Ethernet LAN. If the transmission / reception delay further increases, the PIAFS retransmission control process is started, so that the resynchronization sequence is started between the PHS base station side PIAFS processing units 206 and 216 and the PBX side PIAFS processing units 106 and 116, and the communication speed decreases. Is avoided (step S25).
[0081]
Similarly, when the determination is made on the PBX 10 side, the difference between the time stamp value set by the PIAFS processing unit 116 for the PHS base station 20 and the time stamp value confirmed by the PIAFS processing unit 106 received from the base station is determined, and the PIAFS re-execution Start the synchronization procedure. Since the delay threshold differs depending on the application to be used, it can be changed by the maintenance terminal on the PBX side.
[0082]
As described above, in this embodiment, since the reference base station receives the control signal of the neighboring PHS base station and establishes synchronization, synchronization of the TDMA slot is performed between the PHS base stations connected to the Ethernet LAN that is an asynchronous line. Can be established.
[0083]
In addition, by adding time stamp information to the header part of the message and comparing the time stamp values of the transmission / reception data, it becomes possible to detect the delay of the transmission / reception data. Even if it occurs, this delay can be avoided by starting the resynchronization establishment procedure autonomously.
[0084]
The above-described embodiment is a preferred embodiment of the present invention. However, the present invention is not limited to this, and various modifications can be made without departing from the scope of the present invention. For example, in the above-described embodiment, the delay occurring in the Ethernet LAN is determined using the time stamp value indicating the transmission time. However, this is a count-up value of a counter that is commonly counted up by the PBX 10 and the PHS base station 20. May be. In the above-described embodiment, the control signal transmission interval is 150 ms, 1 PIAFS packet data size is 20 ms, the time stamp value is 32 bits, and the origination identification code is 42 bits. The invention is not limited to these examples. Further, in the above-described embodiment, when the control signal of the private PHS base station instructed from the PBX 10 cannot be detected, the base station of another private PHS system is detected and then the public PHS is detected. The base station is detected. However, the order in which the PHS base stations are detected is not limited to this. For example, a control signal output from either a public PHS base station or a private PHS base station is detected and synchronized therewith. You may do. Further, in the embodiment according to the PHS inter-base station synchronization program of the present invention, the PBX 10 and the PHS base station 20 shown in FIGS. 2 and 3 store a program for performing control according to the procedure shown in FIG. 6 and FIG. This can be realized by the PBX 10 and the PHS base station 20 performing control according to this program.
[0085]
【The invention's effect】
As is clear from the above description, the present invention provides an Ethernet LAN that is an asynchronous line because the PHS base station that has received an instruction from the private branch exchange receives control signals from neighboring PHS base stations and establishes synchronization. TDMA slot synchronization can be established between connected PHS base stations.
[0086]
Also, in data transmission / reception between the private branch exchange and the PHS base station, the transmission side transmits a value indicating the data transmission time at the time of transmission together with the data via the Ethernet LAN, and the reception side is transmitted from the transmission side. By comparing the value indicating the transmission time with the actual reception time of this data, it becomes possible to detect a delay in the Ethernet LAN, and even if a delay occurs in a line that may cause a delay in data transmission, This delay can be avoided by starting the resynchronization establishment procedure autonomously.
[Brief description of the drawings]
FIG. 1 is a diagram showing a system configuration of an embodiment according to the present invention.
FIG. 2 is a block diagram showing a configuration of a PHS signal conversion unit 100 of the PBX 10;
FIG. 3 is a diagram illustrating a configuration of a PHS base station.
FIG. 4 is a diagram illustrating a frame structure of PHS.
FIG. 5 is a sequence diagram showing a procedure for call connection.
FIG. 6 is a flowchart showing an operation procedure of the reference base station.
FIG. 7 is a diagram illustrating a frame structure of PHS.
FIG. 8 is a flowchart showing a procedure for measuring a delay caused by an Ethernet LAN.
[Explanation of symbols]
10 PBX
20 PHS base station
30 PHS mobile terminal
31, 32, 33 PC
34 routers
35 servers

Claims (18)

A system in which a private branch exchange and a plurality of PHS base stations are connected via an Ethernet LAN,
In the plurality of PHS base stations, the private branch exchange device receives a call identification code for identifying a private PHS base station that outputs a radio wave at a predetermined timing, which is input from a maintenance console of the private branch exchange device. Notify any one of the
Upon receiving the notification from the private branch exchange, the PHS base station detects the control signal output from the designated private PHS base station using the originating identification code, and generates a synchronization signal based on the received control signal. Generate and act as a reference station for the PHS base station group ,
The PHS base station other than the PHS base station that has received the notification from the private branch exchange generates a synchronization signal, detects a control signal from the PHS base station that operates as the reference station, and based on the received control signal A synchronization signal is generated and communication is performed between the PHS base stations connected to the Ethernet LAN to synchronize with the PHS mobile terminal .
In data transmission / reception between the private branch exchange and the PHS base station, the transmission side adds an initial value set at the time of call connection to an added value obtained by adding a value obtained by measuring the elapsed time from the call connection. Included in the transmission frame as a value indicating the transmission timing of
The data receiving side compares the added value received via the Ethernet LAN with the added value obtained by adding the value obtained by measuring the elapsed time until the data is received from the call connection to the initial value. Thus, a data delay in the Ethernet LAN is determined, and the PHS inter-station synchronization system is characterized. The PHS base station that has received the notification from the private branch exchange,
If a control signal from the private PHS base station designated by the private branch exchange cannot be detected, connect to a public PHS base station or another private branch exchange different from the private branch exchange 2. The inter-PHS base station according to claim 1, wherein a control signal from the private PHS base station is detected and a synchronization signal is generated based on the received control signal to communicate with the PHS mobile terminal. Synchronous system. The PHS base station that has received the notification from the private branch exchange,
If the control signal from the private PHS base station designated by the private branch exchange cannot be detected, the private PHS base connected to another private branch exchange different from the private branch exchange Detect a control signal from the station, generate a synchronization signal based on the received control signal and communicate with the PHS mobile terminal,
If a control signal from a private PHS base station connected to another switching device different from the private branch switching device could not be detected, the control signal from the public PHS base station was detected and received The synchronization system between PHS base stations according to claim 1, wherein a synchronization signal is generated based on the control signal to communicate with the PHS mobile terminal. The PHS base station that has received the notification from the private branch exchange,
When a control signal from the private PHS base station connected to the public PHS base station or another private branch exchange different from the private branch exchange cannot be detected, an independent clock signal is generated. The PHS base station synchronization system according to claim 2, wherein communication with a PHS mobile terminal is performed. The PHS base station that has received the notification from the private branch exchange,
4. The communication between PHS base stations according to claim 3, wherein when a control signal from the public PHS base station cannot be detected, a clock signal is independently generated to communicate with a PHS mobile terminal. 5. Synchronous system. If the data delay in an Ethernet LAN is determined to have occurred, the claim 1, characterized in that starting the PIAFS resynchronization procedure is PHS data communication protocol according to any one of 5 PHS base station synchronization system. A method for synchronizing PHS base stations in a system in which a private branch exchange and a plurality of PHS base stations are connected via an Ethernet LAN,
In the private branch exchange apparatus, a call identification code for identifying a private PHS base station outputting a radio wave at a predetermined timing is input from a maintenance console of the private branch exchange apparatus, and the input call identification code is Notifying any one of the plurality of PHS base stations,
In the PHS base station that has received the notification from the private branch exchange, the control signal output from the designated private PHS base station is detected by the originating identification code, and the synchronization signal is generated based on the received control signal. Generate and act as a reference station for the PHS base station group ,
In a PHS base station other than the PHS base station that has received the notification from the private branch exchange apparatus, it generates a synchronization signal, detects a control signal from the PHS base station that operates as the reference station, and based on the received control signal A synchronization signal is generated and communication is performed between the PHS base stations connected to the Ethernet LAN to synchronize with the PHS mobile terminal.
In data transmission / reception between the private branch exchange and the PHS base station, the transmission side adds an initial value set at the time of call connection to an added value obtained by adding a value obtained by measuring the elapsed time from the call connection. Included in the transmission frame as a value indicating the transmission timing of
The data receiving side compares the added value received via the Ethernet LAN with the added value obtained by adding the value obtained by measuring the elapsed time until the data is received from the call connection to the initial value. Thus, a data delay in the Ethernet LAN is determined, and the PHS inter-base station synchronization method. In the PHS base station that has received the notification from the private branch exchange apparatus, when a control signal from the private PHS base station designated by the private branch exchange apparatus cannot be detected, a public PHS base station, Alternatively, a control signal from a private PHS base station connected to another private branch exchange different from the private branch exchange is detected, and a synchronization signal is generated based on the received control signal to communicate with the PHS mobile terminal. The PHS inter-station synchronization method according to claim 7, wherein the method is performed. In the PHS base station that has received the notification from the private branch exchange, if the control signal from the private PHS base station designated by the private branch exchange cannot be detected, the private branch exchange and Detects a control signal from a private PHS base station connected to another private branch exchange, generates a synchronization signal based on the received control signal, and communicates with the PHS mobile terminal,
If a control signal from a private PHS base station connected to another switching device different from the private branch switching device could not be detected, the control signal from the public PHS base station was detected and received The synchronization method between PHS base stations according to claim 7 , wherein a synchronization signal is generated based on the control signal to perform communication with the PHS mobile terminal. The PHS base station that has received the notification from the private branch exchange detects a control signal from the private PHS base station connected to the public PHS base station or another private branch exchange different from the private branch exchange 9. The synchronization method between PHS base stations according to claim 8 , wherein if the communication cannot be performed, the clock signal is independently generated to communicate with the PHS mobile terminal. When the PHS base station that has received the notification from the private branch exchange apparatus cannot detect the control signal from the public PHS base station, it independently generates a clock signal to communicate with the PHS mobile terminal. The PHS inter-base station synchronization method according to claim 9, wherein the method is performed. If the data delay in an Ethernet LAN is determined to have occurred, according to any one of claims 7, characterized in that starting the PIAFS resynchronization procedure is PHS data communication protocol 11 Synchronization method between PHS base stations. A PHS base station synchronization program in a system in which a private branch exchange and a plurality of PHS base stations are connected via an Ethernet LAN,
In the private branch exchange apparatus, a call identification code for identifying a private PHS base station outputting a radio wave at a predetermined timing is input from a maintenance console of the private branch exchange apparatus, and the input call identification code is Executing a process of notifying one of the plurality of PHS base stations;
In the PHS base station that has received the notification from the private branch exchange, the control signal output from the designated private PHS base station is detected by the originating identification code, and the synchronization signal is generated based on the received control signal. Generate and execute a process to operate as a reference station of the PHS base station group ,
In a PHS base station other than the PHS base station that has received the notification from the private branch exchange apparatus, it generates a synchronization signal, detects a control signal from the PHS base station that operates as the reference station, and based on the received control signal A process for generating a synchronization signal, synchronizing the PHS base stations connected to the Ethernet LAN, and communicating with the PHS mobile terminal ,
In data transmission between the private branch exchange and the PHS base station, the transmission side adds an initial value set at the time of call connection to a value obtained by adding a value obtained by measuring the elapsed time from the call connection. Execute the process of sending it to the other side as a value indicating the transmission timing of
The data receiving side compares the added value received via the Ethernet LAN with the added value obtained by adding the value obtained by measuring the elapsed time until the data is received from the call connection to the initial value. Thus, a process for determining data delay in the Ethernet LAN is executed . In the PHS base station that has received the notification from the private branch exchange apparatus, when a control signal from the private PHS base station designated by the private branch exchange apparatus cannot be detected, a public PHS base station, Alternatively, a control signal from a private PHS base station connected to another private branch exchange different from the private branch exchange is detected, and a synchronization signal is generated based on the received control signal to communicate with the PHS mobile terminal. The inter-PHS base station synchronization program according to claim 13, wherein a process to be performed is executed. In the PHS base station that has received the notification from the private branch exchange, if the control signal from the private PHS base station designated by the private branch exchange cannot be detected, the private branch exchange and Detects a control signal from a private PHS base station connected to another private branch exchange, executes a process of generating a synchronization signal based on the received control signal and communicating with the PHS mobile terminal,
If a control signal from a private PHS base station connected to another switching device different from the private branch switching device could not be detected, the control signal from the public PHS base station was detected and received The PHS base station synchronization program according to claim 13 , wherein a process for generating a synchronization signal based on the control signal and performing communication with the PHS mobile terminal is executed. The PHS base station that has received the notification from the private branch exchange detects a control signal from the private PHS base station connected to the public PHS base station or another private branch exchange different from the private branch exchange 15. The PHS inter-base station synchronization program according to claim 14 , wherein when the control cannot be performed, a process of generating a clock signal independently and communicating with a PHS mobile terminal is executed. When the PHS base station that has received the notification from the private branch exchange apparatus cannot detect the control signal from the public PHS base station, it independently generates a clock signal to communicate with the PHS mobile terminal. The inter-PHS base station synchronization program according to claim 15, wherein the process is performed. If the data delay in an Ethernet LAN is determined to have occurred, any one of claim 13, wherein performing the process for starting the PIAFS resynchronization procedure is PHS data communication protocol 17 for 1 The PHS base station synchronization program according to Item .

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