JP2015019208A - Subscriber distribution device and signal processing method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a subscriber distribution device capable of dealing with even exchange-side signal input/output path addition or the like, without device expansion or the like, when performing the addition in accordance with fluctuation in the number of devices at connection destinations.SOLUTION: The subscriber distribution device comprises first switch means 71, time-dividing switch means 72 and second switch means 73. In the first switch means 71, time slots allocated to data included in signals inputted from a plurality of input paths at the side of an exchange are converted and then made into one signal and the signal is outputted to a first highway. In the time-dividing switch means 72, the signal inputted via the first highway is demultiplexed and data included in the demultiplexed signals are rearranged in a predetermined order, multiplexed and outputted to a second highway. In the second switch means 73, the signal inputted via the second highway is demultiplexed and outputted to paths at the side of a subscriber accommodation device.

Description

  The present invention relates to communication technology, and more particularly to the technology of a signal distribution device.

  A terminal device such as a telephone can communicate with other terminal devices by distributing signals by each device on the communication network. When the communication network is a telephone network in which a telephone is a terminal device, each telephone that is a terminal device is connected to the subscriber accommodation device via a telephone line. In a telephone network, signals are transmitted / received via a switch between subscriber accommodation apparatuses accommodating telephone lines of individual telephones, so that users of both telephones can talk. A subscriber distribution device for distributing signals is installed between the subscriber accommodation device and the exchange. The subscriber distribution device transmits a signal from the subscriber accommodation device to which the telephone is connected to the exchange corresponding to the telephone line of the call destination. In addition, the subscriber distribution device transmits a signal from the exchange side to the subscriber accommodation device in which the telephone line of the call destination is accommodated. In this way, a telephone call can be made by allocating a bidirectional signal to a route to a predetermined transmission destination by the subscriber distribution device.

  In the subscriber distribution device, signals are distributed by a time division switch provided inside. The subscriber distribution device receives a time-division multiplexed signal from the subscriber accommodation device side or the exchange side. The multiplexed signal input to the subscriber distribution device is input to the time division switch through the highway in the device. After the signals inputted to the time division switch are separated, the signals are sorted for each destination, and the signals for each destination are multiplexed and outputted to the highway to the corresponding exchange. The signal output from the time division switch passes through the highway, is output from the subscriber distribution device, and is sent to the subscriber accommodation device or the exchange.

  The number of telephone lines connected to the subscriber accommodation device often varies due to diversification of communication means, changes in the population of the region, and the like. Therefore, the number of subscriber accommodation devices and exchanges connected to the subscriber distribution device often varies. When the number of subscriber accommodation devices and exchanges connected to the subscriber distribution device varies, the number of highways that send input signals to the time division switch and the number of highways that are output destinations from the time division switch also vary. become. Therefore, when a subscriber accommodation device or an exchange is added, the number of highways and the like in the subscriber distribution device must be increased, which may require a large-scale device configuration change. In addition, when it is assumed that a future highway or the like will be added, it may be necessary to design a large apparatus in order to secure the space. However, it is not desirable that the space occupied by the apparatus increases due to the increase in size, and that the number of operations and the cost increase due to a large-scale apparatus configuration change. Therefore, even if the number of connected subscriber accommodation devices and exchanges varies, the subscriber distribution device can cope with a change in the number of connected devices without requiring a large-scale configuration change or an increase in size. desirable. As a technique related to a subscriber distribution apparatus that can easily cope with a change in the number of subscriber accommodation apparatuses, for example, a technique as disclosed in Patent Document 1 is disclosed.

  In Patent Document 1, it is installed between a plurality of subscriber accommodation devices and a network unit, that is, a subscriber distribution device, and a signal input from one device is multiplexed by a time division switch to the other device. A sending communication device is disclosed. Patent Document 1 shows a connection form of time-division switches that are added in correspondence with subscriber accommodation devices that are added due to an increase in subscribers. In Patent Document 1, it is also possible to connect the line on the network unit side of the time division switch to be added to the port on the subscriber accommodation device side of the already installed time division switch. In Patent Document 1, the number of highways from the subscriber accommodation device side to the network unit, that is, the subscriber distribution device is minimized by adopting such a configuration having time-division switches connected in multiple stages. You can do that. According to Patent Document 1, as a result, it is possible to improve the efficiency of the network unit and suppress the equipment cost.

JP 2000-224625 A

  However, the technique disclosed in Patent Document 1 is not sufficient in the following points. Patent Document 1 discloses only a configuration from a subscriber accommodation device to a network unit, that is, a subscriber distribution device that distributes subscribers, among signal transmission paths from the subscriber accommodation device to an exchange. However, between the subscriber distribution device and the exchange, if any countermeasure is not taken, it is necessary to increase the number of devices and lines according to the increase in the number of exchanges. Increasing the number of lines and circuits in response to an increase in the number of exchanges can increase the size of the apparatus and increase the cost. In addition, there is a possibility that a new line or circuit cannot be installed inside the apparatus due to restrictions on the size of the apparatus. Therefore, the technique described in Patent Document 1 is not sufficient as a technique for suppressing an increase in the size of a device that may occur when the number of connection destination devices increases in the subscriber distribution device.

  The present invention provides a subscriber distribution device that can cope with the addition of a signal input / output path on the exchange side due to a change in the number of connected devices without causing an increase in the size of the device. The purpose is to get.

  In order to solve the above problems, the subscriber distribution device of the present invention includes first switch means, time division switch means, and second switch means. The first switch means converts a time slot assigned to each data included in a signal input from a plurality of input paths on the exchange side, and outputs it to the first highway as one signal. The time division switch means separates the signal input via the first highway, rearranges the order of the data included in the separated signal into a predetermined order, multiplexes and outputs to the second highway . A 2nd switch means isolate | separates the signal input via a 2nd highway, and outputs it to each path | route by the side of a subscriber accommodation apparatus.

  According to the signal processing method of the subscriber distribution device of the present invention, the time slot assigned to each data included in a signal input from a plurality of input paths on the exchange side is converted into one signal and converted into a first signal. Output to highway. According to the signal processing method of the subscriber distribution apparatus of the present invention, the signal input via the first highway is separated, and the order of the data included in the separated signal is rearranged in a predetermined order and multiplexed. To the highway. In addition, the signal processing method of the subscriber distribution device according to the present invention separates the signal input via the second highway and outputs it to each path on the subscriber accommodation device side.

  According to the present invention, even when a signal input path from the exchange side to the subscriber distribution device is added, an increase in the size of the device due to the addition of a line or a circuit can be suppressed.

It is a figure which shows the outline | summary of a structure of the 1st Embodiment of this invention. It is a figure which shows the outline | summary of a structure of the time division switch in the 1st Embodiment of this invention. It is a figure which shows the example of the transmission method of the signal in the 1st Embodiment of this invention. It is a figure which shows the comparison method with the transmission method of the signal in the 1st Embodiment of this invention. It is a figure which shows the outline | summary of a structure of the 2nd Embodiment of this invention. It is a figure which shows the outline | summary of a structure of the 3rd Embodiment of this invention.

  A first embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an outline of the configuration of the subscriber distribution device of this embodiment. The subscriber distribution device 10 of this embodiment includes a subscriber interface circuit 11, a subscriber-side switch interface circuit 12, a time division switch 13, an exchange-side switch interface circuit 14, and an exchange interface circuit 15. A plurality of subscriber interface circuits 11 and exchange interface circuits 15 are provided in accordance with the number of subscriber accommodation devices 31 or exchanges 32 respectively connected thereto. The subscriber interface circuit 11 and the subscriber side switch interface circuit 12 are connected by a switch interface connection highway 23. The subscriber side switch interface circuit 12 and the time division switch 13 are connected by a time division switch connection highway 24. The time division switch 13 and the switch side switch interface circuit 14 are connected by a time division switch connection highway 25. The switch side switch interface circuit 14 and the switch interface circuit 15 are connected by a switch interface connection highway 26. The subscriber interface circuit 11 is connected to a subscriber accommodation device 31 via a subscriber device facing highway 21. The exchange interface circuit 15 is connected to the exchange 32 via the exchange facing highway 22. Each highway has a function of transmitting a time-division multiplexed signal.

  The subscriber interface circuit 11 has a function of converting a signal input from the subscriber device facing highway 21 side into a predetermined signal used in the subscriber distribution device 10. The subscriber interface circuit 11 has a function of converting a signal transmitted from the subscriber-side switch interface circuit 12 into a predetermined signal used in the subscriber apparatus facing highway 21. Which signal conversion function the subscriber interface circuit 11 has is set based on the direction of signal transmission.

  The subscriber-side switch interface circuit 12 includes a subscriber-side concentration switch 41. The subscriber side concentrator switch 41 has a function of multiplexing and outputting signals from each path when signals are inputted from the subscriber interface circuit 11 side. There is no change in the bit rate before and after the signal multiplexing by the subscriber side concentrator switch 41. That is, the bit rates of the signals on the switch interface connection highway 23 and the time division switch connection highway 24 are the same. In addition, when a signal is input from the time division switch 13 side, the subscriber side concentration switch 41 has a function of separating the signal and outputting it to each path. There is no change in the bit rate before and after the signal separation by the subscriber-side concentration switch 41 is performed. Whether the subscriber-side switch interface circuit 12 has a function of multiplexing or demultiplexing a signal is set based on the direction in which the signal is transmitted.

  FIG. 2 shows an outline of the configuration of the time division switch 13. As shown in FIG. 2, the time division switch 13 includes a first switch unit 51, a memory unit 52, a second switch unit 53, and a control unit 54. The first switch unit 51 has a function of switching a path of a signal input to each memory element of the memory unit 52 by switching the switch element. The memory unit 52 has a function of storing input signal data. The second switch unit 53 has a function of switching the path between each memory element of the memory unit 52 and the output side by switching the switch element. The control unit 54 reads the destination of the data stored in each memory element of the memory unit 52, and outputs the data from the memory unit 52 by switching the switch of the second switch unit 53 according to the time slot corresponding to the destination. Has the function to perform.

  The switch side switch interface circuit 14 includes a switch side concentrator switch 42. The function of the switch side concentration switch 42 is the same as that of the subscriber side concentration switch 41. That is, when a signal is input from the exchange interface circuit 15 side, the exchange side concentrator switch 42 multiplexes and outputs signals input from a plurality of paths. When a signal is input from the time division switch 13 side, the exchange-side concentration switch 42 separates the signal and outputs it to each path. There is no change in the bit rate of the signal before and after the switch-side concentrator switch 42. That is, the bit rates of the signals on the time division switch connection highway 25 and the switch interface connection highway 26 are the same.

  The exchange interface circuit 15 has a function of converting a signal input via the exchange facing highway 22 into a predetermined signal used in the subscriber distribution device 10. Further, the exchange interface circuit 15 has a function of converting a signal sent from the exchange side switch interface circuit 14 into a predetermined signal used in the exchange facing highway 22. Which signal conversion function the exchange interface circuit 15 has is set based on the direction of signal transmission.

  Operation when signals from a plurality of exchanges 32 are input to the subscriber distribution device 10, distributed to a predetermined route according to the destination of the signal by the subscriber distribution device 10, and sent to the subscriber accommodation device 31. Will be described.

  A signal inputted from the exchange 32 to the subscriber distribution device 10 via the exchange facing highway 22 is inputted to the exchange interface circuit 15. The exchange interface circuit 15 converts the input signal into a signal of a predetermined format used in the subscriber distribution device 10 and outputs it to the switch interface connection highway 26. The signal output to the switch interface connection highway 26 is transmitted and input to the switch side switch interface circuit 14. The switch side switch interface circuit 14 multiplexes and outputs signals input from a plurality of paths by the switch side concentrator switch 42 provided therein. The signals multiplexed by the switch side concentrator switch 42 are output from the switch side switch interface circuit 14 to the time division switch connection highway 25.

  The signal output to the time division switch connection highway 25 is transmitted and input to the time division switch 13. When a signal is input to the time division switch 13, data included in the input signal is stored in the storage area of each memory element of the memory unit 52 by switching the switch element of the first switch unit 51. When the signal data for one frame is stored in the memory unit 52, the control unit 52 controls the switching of the path by the switch element of the second switch unit 53 and outputs the data stored in the memory unit 52. Do. The control unit 54 reads the destination of each data stored in the memory unit 52, and outputs the data stored from the memory unit 52 so as to match the time slot assigned to each subscriber accommodation device 31 serving as the destination. . The control unit 54 controls the second switch unit 53 to output data from the memory unit 52 when the output order to the time slot corresponding to the destination of each data stored in the memory unit 52 has come. I do.

  A signal composed of data output from the memory unit 52 of the time division switch 13 is output to the time division switch connection highway 24. The signal output to the time division switch connection highway 24 is transmitted and input to the subscriber side switch interface circuit 12. When a signal is input to the subscriber-side switch interface circuit 12, the subscriber-side concentrator switch 41 separates the input signal by switching the switch element for each time slot of the input signal, and sequentially enters each path. Output. The signal output to each path by the subscriber line concentrator switch 41 is output to the switch interface connection highway 23. Each signal output to the switch interface connection highway 23 is transmitted and input to the subscriber interface circuit 11. When a signal is input to the subscriber interface circuit 11, the subscriber interface circuit 11 converts the signal into a predetermined signal used for communication with the subscriber accommodation device 31 and outputs the signal. The signal output from the subscriber interface circuit 11 is sent to the subscriber accommodation device 31 via the subscriber device facing highway 21.

  With reference to FIG. 3, the signal processing method in the subscriber distribution device 10 will be described in more detail. FIG. 3 shows a state in which signals are input from the two exchanges 32 to the subscriber distribution device 10 of the present embodiment until the signals reach the time division switch 13. Assume that one of the exchanges 32 is exchange A and the other is exchange B. Of the two exchange interface circuits 15, it is assumed that the exchange interface circuit A receives a signal from the exchange A and the exchange interface circuit B receives a signal from the exchange B. Of the signal paths from the switch 32 to the time division switch 13, the path including the switch A and the switch interface circuit A is referred to as a first path. Of the signal paths from the switch 32 to the time division switch 13, a path including the switch B and the switch interface circuit B is referred to as a second path.

  It is assumed that a signal including data in the order of “C1, empty, C2, empty” is input to the exchange interface circuit A from the exchange A via the exchange facing highway 22 in the first path. Similarly, assume that a signal including data in the order of “empty, empty, D1, D2” is input from the exchange B to the exchange interface circuit B in the second path. “C1”, “C2”, “D1”, and “D2” are data that occupy one time slot, and “empty” indicates that no data is included in the corresponding time slot. The exchange interface circuit A and the exchange interface circuit B convert the inputted signals into signals of a predetermined system and output them in the order of the inputted signals. The signals output from the exchange interface circuit A and the exchange interface circuit B are respectively input to the exchange side switch interface circuit 14 through the switch interface connection highway 26.

  The switch-side concentrator switch 42 of the switch-side switch interface circuit 14 multiplexes signals input from two paths and outputs them as one signal. The switch-side concentrator switch 42 switches the switch elements so that the data of the signal input from the first path among the signals input from the two paths can be output. Since “C1” data is included in the first time slot of the signal of the first path, the exchange-side concentration switch 42 outputs “C1” data. Next, the exchange-side concentration switch 42 switches the switch elements so that data included in the first time slot of the second path is output. However, the first time slot of the second route is in an “empty” state and contains no data. Therefore, the switch-side concentrator switch 42 switches the switch elements so as to output the data of the second time slot of the first path in the next order without outputting the data. Further, since the second time slot of the first path is also in the “vacant” state, the exchange side concentrator switch 42 switches the switch element so as to output the data of the second time slot of the second path. Since the second time slot of the second path is also in the “vacant” state, the switch side concentrator switch 42 switches the switch elements so as to output the data of the third time slot of the first path.

  Since the third time slot of the first route includes “C2” data, the switch-side concentration switch 42 outputs “C2” data. Next, the switch-side concentration switch 42 switches the switch elements so as to output the data of the third time slot of the second path. Since the third time slot of the second route includes the data “D1”, the exchange side concentrator switch 42 outputs the data “D1”. Next, the switch side concentrator switch 42 switches the switch elements so as to output the data of the fourth time slot of the first path. Since the data of the fourth time slot of the first path is in the “vacant” state, the exchange side concentrator switch 42 switches the switch element so as to output the data of the fourth time slot of the second path. Since the fourth time slot of the second path includes the data “D2”, the exchange side concentrator switch 42 outputs the data “D2”. With the above operation, the switch side concentrator switch 42 outputs data in the order of “C1, C2, D1, D2.” Further, when there is a signal input from each path, the exchange-side concentration switch 42 repeats the above operation.

  A signal composed of the data of “C1, C2, D1, D2” output from the switch side concentrator switch 42 is output from the switch side switch interface circuit 14 to the time division switch connection highway 25. A signal composed of the data “C1, C2, D1, D2” output to the time division switch connection highway 25 is input to the time division switch 13.

  FIG. 4 shows the signal flow in the subscriber distribution device when the switch-side switch interface circuit 16 not provided with the switch-side concentrating switch is used. Since no subscriber line concentrator switch is provided, the signals “C1, vacant, C2, vacant” and “vacant, vacant, D1, D2” are transmitted on the two time division switch connection highways 27, respectively. When the switch side switch interface circuit 16 that does not include the switch side concentrator switch is used, the subscriber side concentrator switch does not multiplex signals of a plurality of paths, and therefore there is a time slot in an “empty” state. Probability is high. On the other hand, in the present embodiment, when there is an empty time slot in the signal of each empty route, the exchange side concentrator switch 42 outputs data included in the next time slot of the other route. Move to operation. Therefore, there is no empty time slot in the signal output from the switch side concentrator switch 42. For this reason, the time division switch connection highway 25 enables efficient signal transmission with no vacant state between data included in the signal. Even when the number of exchanges 32 to be connected increases and the amount of communication increases by performing efficient signal transmission in the time division switch connection highway 25, the number of new time division switch connection high phases 25 is not increased. The possibility of being able to respond increases.

  The operation when the signal from the exchange 32 is input to the subscriber distribution device 10 and the signal is transmitted to the subscriber accommodation device 31 has been described above. In the subscriber distribution measure 10 of the present embodiment, when a signal is transmitted in the reverse direction, that is, a signal from the subscriber accommodation device 31 is input, and the signal distributed according to the destination is transmitted to the exchange 32. Can also be used.

  The subscriber distribution device according to this embodiment includes an interface circuit having a concentrator switch on the input side and output side of the time division switch. By adopting such a configuration, it is possible to improve the efficiency of signal transmission on the time division switch connection highway. Further, even if the number of input signal paths increases due to an increase in the number of subscribers or a change in the connection configuration with the switch, it is not necessary to increase the number of switch-side switch interface circuits and time-division switch connection highways. Therefore, even when an exchange or the like needs to be added, it is possible to cope with a change in the network configuration by suppressing an increase in the size of the apparatus.

  A second embodiment of the present invention will be described in detail with reference to the drawings. FIG. 5 shows an outline of the configuration of the subscriber distribution device of this embodiment. In the first embodiment, only one exchange-side switch interface circuit including an exchange-side concentrator switch is provided. However, the subscriber distribution device of this embodiment includes a plurality of exchange-side switch interface circuits.

  The subscriber distribution device 60 of this embodiment includes a subscriber interface circuit 61, a subscriber-side switch interface circuit 62, a time division switch 63, and a first switch-side switch interface circuit 64. The subscriber distribution device 60 of this embodiment further includes an exchange interface circuit 65, a second exchange side switch interface circuit 66, and an exchange interface circuit 67. A plurality of subscriber side switch interface circuits 62 and switch interface circuits 65 are provided according to the number of subscriber accommodation devices 31 or switches 32, respectively. The subscriber interface circuit 61 and the subscriber-side switch interface circuit 62 are connected by a switch interface connection highway 23. The subscriber side switch interface circuit 62 and the time division switch 63 are connected by a time division switch connection highway 24. The time division switch 63 and the first switch side switch interface circuit 64 are connected by a time division switch connection highway 25. The first switch side switch interface circuit 64 and the switch interface circuit 65 are connected by a switch interface connection highway 26. The first switch side switch interface circuit 64 and the second switch side switch interface circuit 66 are connected by an inter-switch interface connection highway 28. The switch interface connection highway 29 is connected between the second switch side switch interface circuit 66 and the switch interface circuit 67.

  The subscriber interface circuit 61 is connected to the subscriber accommodation device 31 via the subscriber device facing highway 21. The exchange interface circuit 65 is connected to the exchange 32 via the exchange facing highway 22. The exchange interface circuit 67 is connected to the exchange 33 via the exchange facing highway 30. Each highway has a function of transmitting a time-division multiplexed signal.

  The configurations and functions of the subscriber interface circuit 61, the subscriber-side switch interface circuit 62, the time division switch 63, the exchange interface circuit 65, and the exchange interface circuit 67 of the present embodiment are parts having the same names as those of the first embodiment. It is the same. The first switch side switch interface circuit 64 and the second switch side switch interface circuit 66 have the same configuration and function as the switch side switch interface circuit of the first embodiment.

  An operation when a signal from the exchange 32 is input to the subscriber distribution device 60 and distributed according to the destination in the subscriber distribution device 60 will be described. The signal transmission method through the path of the signal from the switch 32, that is, the path input to the first switch interface circuit 64 without passing through the second switch interface circuit 66 is the same as that of the first embodiment. Next, a signal transmission method on a route passing through the second exchange interface circuit 66 will be described.

  It is assumed that a signal is input from the exchange 33 to the exchange interface circuit 67 via the exchange facing highway 30. The signal input to the exchange interface circuit 67 is converted into a predetermined signal used in the subscriber distribution device 60 and output. The signal output from the exchange interface circuit 67 is input to the second switch interface circuit 66 via the switch interface connection highway 29. The signals input to the second switch interface circuit 66 are multiplexed by the switch side concentrator switch 43 and output as one signal. Multiplexing at the switch-side concentrator switch 43 is performed in the same manner as in the switch interface circuit of the first embodiment. When there is one signal path input to the second switch interface circuit 66 and there is data in each time slot, the order of the input signal and the data order of the output signal changes. do not do. If the input signal has one path and the input signal has a vacant time slot, the data of the time slot after the vacant time slot is carried forward and output.

  The signal output from the switch side concentrator switch 43 is output from the second switch side switch interface circuit 66 to the switch interface connection highway 28. The signal output to the switch interface connecting highway 28 is transmitted and input to the first switch side switch interface circuit 64. When a signal is input to the first switch side switch interface circuit 64, it is multiplexed by the switch side concentrator switch 42 together with a signal input from another path, and is output as one signal. The switch side concentrator switch 42 multiplexes signals input from a plurality of paths and outputs it as one signal by the same operation as the switch side concentrator switch of the switch side switch interface circuit of the first embodiment. The signal output from the switch side concentrator switch 42 is output from the first switch side switch interface circuit 64 to the time division switch connection highway 25. The signal output to the time division switch connection highway 25 is transmitted and input to the time division switch 63. The operation after input to the time division switch 63 is the same as that of the first embodiment.

  The operation when the signals from the exchange 32 and the exchange 33 are input to the subscriber distribution device 60 and the signal is transmitted to the subscriber accommodation device 31 has been described above. In the subscriber distribution measure 60 of the present embodiment, when a signal is transmitted in the reverse direction, that is, when a signal from the subscriber accommodation device 31 is input, the signal distributed according to the destination is the exchange 32 or the exchange 33. It can also be used when transmitted to.

  In the subscriber distribution device according to the present embodiment, switch-side switch connection interface circuits having concentrator switches are connected in multiple stages. Therefore, even when the number of paths of signals input from the exchange side to the subscriber distribution apparatus increases, it is possible to cope with the situation without newly increasing the time division switch connection highway on the exchange side than the time division switch. As a result, even when an exchange or the like is added, an increase in the size of the apparatus due to an increase in time-division switch connection highways or the like can be suppressed.

  In the first or second embodiment, a configuration may be adopted in which test signals can be transmitted and received between the exchange and the exchange-side concentration switch. In that case, the exchange inserts a test signal into an empty time slot and transmits it to the subscriber distribution device. When the switch side concentrator switch of the subscriber distribution device receives the test signal, it returns the test signal to the switch, and the switch determines whether there is a communication line or communication abnormality based on the returned test signal. By adopting such a configuration, it is possible to detect the presence or absence of an abnormality between the exchange and the subscriber distribution device, so that it is possible to quickly cope with the abnormality and improve communication reliability. .

  A third embodiment of the present invention will be described in detail with reference to the drawings. FIG. 6 shows an outline of the configuration of the subscriber distribution device of this embodiment. The subscriber distribution device of this embodiment includes first switch means 71, time division switch means 72, and second switch means 73. The first switch means 71 converts a time slot assigned to each data included in a signal input from a plurality of input paths on the exchange side, and outputs it to the first highway as one signal. The time division switch means 72 separates the signal input via the first highway, rearranges the order of the data included in the separated signal into a predetermined order, multiplexes and outputs to the second highway To do. The second switch means 73 separates the signal input via the second highway and outputs it to each path on the subscriber accommodation device side.

  In the subscriber distribution device of this embodiment, signals input from a plurality of routes on the exchange side are multiplexed by the first switch means 71 and then input to the time division switch means 72. Therefore, the transmission of signals between the first switch means 71 and the time division switch means 72 can be made efficient. As a result, even when the number of signal input paths is increased, it is not necessary to install a new path between the first switch means 71 and the time division switch means 72, which increases the size and cost of the apparatus by adding lines and circuits. The increase can be suppressed.

  The present invention can be used for a communication system, and in particular, for a communication system such as a telephone call system.

DESCRIPTION OF SYMBOLS 10 Subscriber distribution apparatus 11 Subscriber interface circuit 12 Subscriber side switch interface circuit 13 Time division switch 14 Switch side switch interface circuit 15 Switch interface interface circuit 21 Subscriber apparatus opposite highway 22 Switch opposite highway 23 Switch interface connection highway 24 Time division switch Connection Highway 25 Time-Division Switch Connection Highway 26 Switch Interface Connection Highway 27 Time-Division Switch Connection Highway 28 Inter-Switch Interface Connection Highway 29 Switch Interface Connection Highway 30 Switch-facing Highway 31 Subscriber Accommodating Device 32 Switch 33 Switch 41 41 Subscriber Side Concentration Switch 42 Switch side concentrator switch 43 Switch side concentrator switch 51 First switch section 52 memory section 53 second switch section 54 control section 60 subscriber distribution device 61 subscriber interface circuit 62 subscriber side switch interface circuit 63 time division switch 64 first switch side switch interface circuit 65 switch interface circuit 66 second Switch side switch interface circuit 67 Switch interface circuit 71 First switch means 72 Time division switch means 73 Second switch means

Claims (9)

A first switch means for converting a time slot assigned to each data included in a signal input from a plurality of input paths on the exchange side and then outputting it as a single signal to the first highway;
Time-division switch means for separating a signal input via the first highway, rearranging the order of data included in the separated signal in a predetermined order, and multiplexing and outputting to the second highway ,
And a second switch means for separating a signal inputted via the second highway and outputting the separated signal to each path on the subscriber accommodation device side.   The first switch means performs the output operation of the data of the signal of the input path in the next order when the data is not included in the corresponding time slot of the signal of the input path that has been turned in the order of output. The subscriber distribution device according to claim 1, wherein the subscriber distribution device is performed. Further comprising third switch means for outputting a signal input from a plurality or a single input path on the exchange side as a multiplexed signal;
3. The subscriber distribution device according to claim 1, wherein a signal output from the third switch means is input to the first switch means.   The subscription according to any one of claims 1 to 3, further comprising test signal processing means for receiving a test signal input via the input path on an exchange side and transmitting a response signal to the test signal. Person distribution device. A plurality of exchanges, a plurality of subscriber accommodation devices, and the subscriber distribution device according to any one of claims 1 to 4,
A signal is input from the exchange to the subscriber distribution device via a communication line,
A communication system, wherein a signal output from the subscriber distribution device is input to the subscriber accommodation device via a communication line. A plurality of exchanges, and a subscriber distribution device according to claim 4,
The switch has means for transmitting a test signal, means for receiving a response signal to the test signal, and means for judging whether or not there is a line abnormality based on the received response signal;
The test signal from the switch is input to the subscriber distribution device via a communication line, and the response signal from the subscriber distribution device that has received the test signal is input to the switch via the communication line. A communication system. After converting the time slot allocated to each data included in the signal input from the plurality of input paths on the exchange side, it is output as a single signal to the first highway,
Separating a signal input via the first highway, rearranging and multiplexing the order of data included in the separated signal in a predetermined order, and outputting to the second highway;
A signal processing method of a subscriber distribution device, wherein a signal input via the second highway is separated and output to each path on the subscriber accommodation device side.   The output operation of the data of the signal of the input path in the next order is performed when data is not included in the corresponding time slot of the signal of the input path from which the order of output has come. 8. A signal processing method for a subscriber distribution device according to claim 7. Output signals input from multiple or single input paths on the switch side as multiplexed multiplexed signals,
9. The subscriber distribution according to claim 7, wherein the multiplexed signal is further time-division multiplexed with a signal input from another input path on the exchange side and output to the first highway. Device signal processing method.

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