JPS6326100A - Exchange system - Google Patents

Abstract

PURPOSE:To prevent the deterioration in a processing capacity due to the increase in the load of a signal processor by providing two signal communication paths in a D channel packet and switching a signal passing path as a necessary. CONSTITUTION:Ordinarily, the signal passing path passing the signal processor is used, and when subscribers requesting for a permanent fixing connection are connected, with each other, or when the traffic of the D channel packet on a subscriber's line is increased, the signal passing path is switched to the signal passing path which does not pass the signal processor. When the D channel packet of 16 Kb/s is transmitted from the subscriber having a (2B+D) structure stored in the subscriber's line 1-1 to the subscriber stored in the subscriber's line 13-1, the former reaches via a subscriber line terminal device 2-1, a separator 3-1 to the signal processor 5 and is inputted to a multiplex device 6 after the processing. The latter reaches via the subscriber line terminal device 2-1, the separator 3-1, a time division switch 4 to the multiplex device 6.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a switching system, and more particularly to a switching system for subscribers having a 2B+D structure according to the CCITT Recommendation Nigillies in an I5DN switching system.

[Conventional technology]

FIG. 2 is a block diagram of a conventional switching system that accommodates 2B+D structure subscribers. Subscriber lines 14-1 to 14- connected to subscribers having a 2B+D structure interface
n is terminated by subscriber line termination devices i5-+ to 15-n. 2 of 15-n to subscriber line termination device 15-1
The 8+D outputs are separated into two 64 Kb/s B channels and one 16 Kb/s D channel per subscriber by separation devices 16-1 to 16-n, and the two B channels per subscriber are time-divided. Switch 17 is powered manually.

One D channel per subscriber is input to signal processing unit 18. The output of the time division switch 17 is the multiplexer 19
It is man-powered. Also, a signal processing device! The output of 8 is also manually input to the multiplexer 19. The output of the multiplexer 19 is
The signal is input to the separation device 21 via the digital transmission line 20. The output of the separation device 21 is manually input to a time division switch 22 and a signal processing device 23. Furthermore, the output of the time division switch 22 and the output of the signal processing device 23 are transferred to a multiplexer 24.
-1 to 24-m, subscriber line terminal device 25-1
25-m to subscriber lines 26-1 to 26-a+.

A digital signal having a 28+D structure on the subscriber line 14-1 is input to the separating device +6-1 after being terminated by the subscriber line terminating device 15-1. In the separation device 16-1, a human signal with a 2B+D structure is sent to two 64 b/s B
channel and one 16Kb/S D channel,
The two B channels output to the time division switch, and one D channel outputs to the signal processing device I8. Time division switch 17
In this case, two B channels per subscriber are time-divisionally switched, and k 64 Kb/s B channels are transferred to multiplexer 1.
Output to 9. Separation device +6-1 in signal processing device 18
-16 b/s n per subscriber output from -16-n
The time division switch 17 is controlled, and the 64 Kb/s D channel destined for the opposing signal processing device 23 is outputted to the multiplexer 19 via the digital transmission line 20. The multiplexer 19 has 64 b/s B channels manually inputted by an integer of 1 or more, and 1
The 64 Kb/s D channels are multiplexed and sent to the digital transmission line 20.

On the other hand, the signal input from the digital transmission line 20 to the demultiplexing device 21, which is a multiplexed signal of 1 64 b/s B channel and 1 64 b/s D channel, is
The k 64Kb/s B channels are input to the time division switch 22, and the k 64Kb/s D channels are separated into one 64Kb/s B channel and one 64Kb/s D channel. is input to the signal processing device 23. The signal processing device 23 decodes the 64 b/s D channel from the opposing signal processing device 18 via the digital transmission line 20, controls the time division switch 22, and distributes it to each subscriber. s D channels are output to m multiplexers 24-1 to 24-m, which are integers greater than or equal to 1. In the time-division switch 22, under the control of the signal processing device 23, the B channel of b/s is manually time-division exchanged to 64 multiplexers 24-1 to 24-1 to be distributed.
Output to 11. In the multiplexers 24-1 to Z4-m, 16 b/s D channels and two 64K
b/s B channel and subscriber line 26-1.
~26-l via subscriber line termination devices 25-1~25-m.

With the configuration and operation described above, in a pair of opposing subscribers, two 64 b/s B channel signals are connected via the time division switch 17.22, and one
Two 16 b/s D channel signals are processed by the signal processing device 18
．． 23 and one 64 Kb/s transmission line channel.

(Problems to be Solved by the Invention) In the above-mentioned conventional switching system accommodating subscribers with a 2B+D structure, the frequency of use of the 16 Kb/s D channel per subscriber, that is, the D channel packets of the subscriber increases. In this case, the processing capacity of the signal processing device and the 6
Even for subscribers who are running out of D-channel capacity at 16 b/s and who require a permanent fixed connection, i.e., a leased line network, the signal processing equipment is constantly
D channel signal and also 64K on the transmission path
Since the signal processing devices will use the b/s D channel to send and receive D channel signals, the processing capacity of the signal processing devices and the b/s D channel capacity on the 64 transmission path will be insufficient. There are drawbacks.

It is an object of the present invention to withstand an increase in the number of D channel packets of subscribers, and to increase the capacity of a signal processing device and 64 b/s on a transmission path for D channel packets of permanently connected subscribers. An object of the present invention is to provide a switching system that does not reduce D channel capacity.

[Means for solving problems]

The switching system of the present invention includes a subscriber line termination device accommodating subscribers having a 2B+D structure, and a first
a multiplexing/demultiplexing device, a time division switch connected to the first multiplexing/demultiplexing device and outputting the separated B channel and D channel, and a first multiplexing/demultiplexing device connected to the time division switch. and a signal processing device that outputs the D channel separated by the switch, and also processes the input D channel into a signal for each subscriber and outputs it to the time division switch. is an exchange that inputs and outputs the B channel and D channel, and the signal processing device has a second multiplexing/demultiplexing device that inputs and outputs the D channel, and a digital transmission line connected to the second multiplexing/demultiplexing device. system.

That is, the present invention inputs one 16B/s D channel signal per subscriber to the signal processing device, and also inputs one 64K D channel signal output from the separation device and input to the signal processing device.
Input the b/s D channel signal to the time division switch,
When two signal paths are provided for D-channel packets, usually through a signal processing device, to connect subscribers requiring a permanent fixed connection, or for D-channel packets on subscriber lines. When traffic increases, by switching to a signal passing route that does not pass through the signal processing device, it is possible to prevent a decline in processing capacity due to an increase in the load on the signal processing device, and to reduce the number of b/s D
This allows channels to be used effectively.

(Example) Next, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of the exchange system of the present invention.

Subscriber lines l-1-1-n of integer n greater than or equal to 1 are connected to n subscriber line termination devices 2-1 to 2-n. n
Outputs of the subscriber line termination devices 2-1 to 2-n are connected to n separation circuits 3-1 to 3-n. The outputs of the n separation circuits 3-1 to 3-n are divided into two 64 b
/s to time division switch 4 and one +6 Kb/s D channel per subscriber to time division switch 4.
and is connected to the signal processing device 5. Time division switch 4
The 64 Kb/s signals are input to the multiplexer 6. Also, the b/s D channel signal is sent to 64 of the signal processing device 5. It is input to the heavy equipment 6. The signal processing device 5 can control the time division switch 4 via a control line. The output of the multiplexer 6 is connected to a demultiplexer 8 via a digital transmission line 7. Separation device 8 to 64b
/s signal output is input to the time division switch 9.

Further, the b/s D channel signal 64 of one of the separation devices 8 is inputted to the signal processing device IO. The m 16 b/s D channel signals of the signal processing device IO are manually inputted to the time division switch 9. Two 64 b/s B channel signals per subscriber and one 16 b/s D channel signal per subscriber of the time division switch 9 are multiplexed by +1
-1 to fin are input. Multiplexer 1l-IN1+-
The 2B+D signals multiplexed by n are sent to subscriber lines +3-1 to 13 via subscriber line termination devices +2-1 to 12-n.
−+n. Note that the signal processing device IO can control the time division switch 9 via a control line.

In this switching system, when a subscriber with a 2B+D structure accommodated in subscriber line 1-1 sends a D channel packet of 16 b/s to a subscriber accommodated in subscriber line +3-1, The following two ways are possible.

In the first case, the D channel packet on the subscriber line 1-1 reaches the signal processing device 5 via the subscriber line termination device 2-1 and the demultiplexing device 3-1, and is processed by the multiplexer. 6,
The signal is inputted to the signal processing device IO via the digital transmission line 7 and the separation device 8. The D channel signal processed into a D channel signal for each subscriber by the signal processing device IO is sent to a time division switch 9, a multiplexer ++-1, and a subscriber line termination device 12.
-1 onto the subscriber line 13-1.

In the second case, the D channel packet on the subscriber line 1-1 reaches the multiplexer 6 via the subscriber line termination device 2-11, the separation device 3-1, and the time division switch 4. Multiplexer 6
Now, the D channel packet signal from the time division switch 4 is multiplexed into one of the k channels,
The signal is sent to the opposing separation device 8 via the digital transmission line 7. The minute+11 device 8 manually sends all the signals of the channels to the time division switch 9, and the time division switch 9 sends the D channel bucket signals of the channels to the multiplexer 11-1. Sort it out. Thereafter, it is sent to the subscriber line 13-1 via the multiplexer 11-1 and the subscriber line termination unit 12-1.

〔Effect of the invention〕

As explained above, the present invention provides two
When two signal communication paths are provided to connect subscribers who require a permanent fixed connection, or when the traffic of D channel packets on the subscriber line increases, the first case to the second case is used. By switching the signal passage path depending on the case, it is possible to prevent a decrease in processing capacity due to an increase in the load on the signal processing device, and to effectively utilize the 64 b/s D channel on the transmission path.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the switching system of the present invention, and FIG. 2 is a block diagram of a conventional switching system. 1-1 to I-n - subscriber line, 2-1 to 2-n - subscriber line termination device, 3-1 to 3-n - separation circuit, 4 - time division switch,
5... Signal processing device, 6... Multiplexing device, 7.
... Digital transmission line, 8 ... Separation device, 9 ... Time division switch, 10 ... Signal processing device, +1-1
〜II-m...Multiplex device, 12-1〜l 2-to-=Subscriber line terminal device, 13
-1 to 13-m = subscriber line.

Claims (1)

[Scope of Claims] A subscriber line terminating device accommodating subscribers having a 2B+D structure; a first multiplexing/demultiplexing device connected to the subscriber line terminating device and multiplexing/demultiplexing B channels and D channels; A time division switch connected to the first multiplexing/demultiplexing device and inputting/outputting the separated B channel and D channel; and a time division switch connected to the time division switch and outputting the D channel separated by the first multiplexing/demultiplexing device. There is also a signal processing device that processes the input D channel into a signal for each subscriber and outputs it to the time division switch.The time division switch is connected to the time division switch and the signal processing device. A switching system having a second multiplexing/demultiplexing device for inputting/outputting a D channel, and a digital transmission line connected to the second multiplexing/demultiplexing device.