CA1292053C - Time-division channel arrangement - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE
A switching system for integratedly switching voice, data, image information and the like. The switching system comprises a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line, and a single or a plurality of central modules for interconnecting the plurality of front-end modules in star-type fashion and switching information prevailing between the front-end modules, in unit of block accommo-dating the information and a header added thereto to contain connection control information and in accordance with the contents of the header. The front-end modules are connected to the central module via inter-module highways each having frames occurring at a predetrmined period and time slots contained in each frame to carry blocks.

Description

~i3 BACKGROUND OF THE INVENTIO~
Field of the Invention This invention relates to a switching system adapted to perform switching processings of voice, data, image information and the like and more particularly to a time-division channel arrangement suitable for performing switching of information, in a unit of a block accommodating communication control information, between switching nodes or modules in a star-type configuration.
Description of the Related Art In the field of the switching system, studies have been concentrated on realiæation of high-speed and wide band performance, increase in the capacity of the channel and advanced improvements in reliability. Conceivably, a specified expedient to this end resides in the distribution of a channel system, especially, a multiplexer stage.
This expedient takes advantage of the distribution of load which contributes to improvement in throughput and of an increase in the capacity of the overall exchange and the distribution of the physical configuration which contributes to the distribution of danger.
In the past, the exchange has played a major role in switching low-speed telephone voice, but it is expected that high-speed data communications are applicable to ;:: : : :

-:

'~' ~29;~i3 image data will be in great demand in future. Under ~he circumstances, the exchange is required to be drastically improved in call throughput but throughput of a processor cannot be extended unlimitedly. To promote the throughput of the processor, the distribution of function and the distribution of load based on a multi-processor scheme may conceivably be adopted. This countermeasure, however, invites complexity of software and besides sufers from a bottleneck caused by communications between processors and the like factor, thus failing to eliminate the limitation imposed on the throughput.
Incidentally, from the standpoint of the enlargement of the system and the distribution of danger, it is desirable that individual function units of the exchange be realized with individual modules and these modules be physically distributed. In such an instance, unless an independent distribution configuration is adopted wherein processors per se are distributed, the load will be concentrated on a central processor and inconveniently the number of lines for controlling each distributed module will be increased.
In a distributed type switching system in which the speech path system is distributed and the control ~ system is concentrated at a location, throughput of the control~system is limlted and the merits of the distribution of load cannot fully mature to advantage.
Under the circumstances, a foreseen switching system ' ' ~LX9Z053 1 is desired to be of an independent distributed configu-ration in which not only the speech path system but also the control system is distributed. The use of independent modules is however problematic in that when a module communicates with another module, the sending module has to know whether a channel to the partner module is idle and whether an outgoing circuit from the partner module is idle. In other words, resource management is needed. Even in the ordinary distributed ~10 system, resource management is often concentrated at a location and all modules interrogate a common managing unit. Consequently, a bottleneck of processing is caused by the managing unit, especially, in a large-scaIe system. On the other hand, the system of full I5 independent distributed modules is forced to take either a way to enable one module to constantly know the status of all of the other modules or a way to permit one module to confirm the status of the partner module each time a call is set up. In the former way, one module, when its status changes, is required to inform all remaining modules of the change or all of the modules must mutually confirm their status periodically. Even wi~th the above procedure completed, when a module has only~one idle circuit, there lS a possibility that the remalning modules will transmit communication requests to that module at the same time. In the latter way, the above problems are not encountered but the necessity of mutual Fommunications among all of the modules is by .

12920~3 1 itself problematic. As a countermeasure, it is conceivable to establish communication lines in a mesh configuration among the modules. However, this becomes costly due to the complicated physical geometry and due to the fact that additional management of communi-cation is needed.
Incidentally, in recent years, the trend of integratedly communicating various kinds of information including voice and data has become active. This trend originates from a desire for ef~iciency and economization but realization of the integra ed communications need~
integrated switching processings of various kinds of information. In particular~ it is desired that switching of circuit switching informatlon such as voice of which real-time base processings are required and switching of storable data or storage switching information which has hitherto been handled by a packet exchange can both be effected integratedly through the same channel.
A time-division channel arrangement for integratedly handling voice and data, that is, a so-called integrated channel arrangement is known as disclosed in JP-A-61-60044 entitled "Block switching system" and JP-A-60-127844 entltled "Circuit/packet integrated switching system". In the former literature, also as disclosed in Proceedings of International ; Switching Symposium 1987 SESSION B.7.1 "ELASTIC BASKET
SWITCHING -- A NEW INTEGRATED SWITCHING SYSTEM FOR
VOICE AND HIGH-SPEED BURST DATA --" by S. Morita et al, , . , ~Z920~3 1 a boundary identifier indicative of the boundary between communication channels is dynamically set in accordance with the amount of information in a set-up call in order that either of information requiring real-time base processing and information re~uiring burst base processing can be switched one-dimensionally.
In the latter literature, also as disclosed in Proceedings of International Switching Symposium 1984 SESSION 42B-3 "S~NCHRONOUS COMPOSITE PACKET SWITCHING FOR ISDN
S~ITCHING SYSTEM ARCHITECTURE" by T. Takeuchi et al, a plurality of distributed communication nodes are connected in loop, the communication node being a switching module having a subscriber interface or a trunk interface, and each switching module packets circuit switching information such as voice and packet switching information such as data in bIocks of fixed length in accordance with destination switching modules and adds a destination node number to each block, so that the information may be switched through the loop channel.
In the aforementioned "Block switching system", the time switch function of the channel can efficiently be realized but because of each block being of a variable length, the space switch function of the channel for mutually rearranging blocks on a highway is difficult to achieve. Accordingly, this system is unsuitable for a large-scale exchange.
In the aforementioned "Circuit/packet 129X~S3 1 integrated switching system", on the other hand, all of the switching modules access the loop and in order to prevent the overall throughput from being decreased, the loop must be operated at so high a speed that the total of amounts of throughput of the individual modules can be handled by the loop. Accordingly, ~he larger the scale of the exchange, the more the high-speed device will be used in the interface between each switching module and the loop becomes expensive.
In order to solve these problems, it is effective to use a block of fixed length which accommo-dates connection information and to construct a self-routing network which does not use a loop. However, while the use of the loop is convenient in that all the blocks carried on the loop can be processed sequentially with ease, a plurality of blocks used in, for example, the star-type configuration must be rearranged to prevent them from colliding with each other at a time within the central node. To this end, avoidance of concentration of individual blocks on a specified connection destination (outgoing highway) is necessary and blocks once stored must be controlled : for switching such that they do not collide with each other, by monitoring destinations of individual blocks.
However, in the case of switching communication infor-mation, intensively bursty, as appearing in a kind of data communications (for example, image information transfer), many blocks must be sent to the same ~292~53 1 destination within a short period of time but in the case of switching information requiring real-time base processing, such as voice, storage of blocks must be avoided as far as possible.
Reference may be made to JP-A-5~-23658, USP
4,494,230 and International Publication No. ~085/02735 (coressponding to JP-A-60-501833).

SUMMARY OF THE INVENTION
An object of the present invention is to provide an economical and high~throughput switching system.
Another object of the invention is to provide a highly reliable switching system based on the distri-bution of load and the dispersion of danger.
Still another object of the invention is to provide a time-division channel arxangement capable of meeting both the requests for real-time base processing and burst base processing.
According to the invention, to accomplish the above objects, a switching system comprises a plurality of front-end modules each~adapted to perform a switching processing in association with a subscriber line or a trunk line, and a single or a plurality of central modules for interconnecting the plurality of front-end modules in star-type fashion via highway~ and switching information prevailing between the front-end modules, in a unit of a block accommodatillg the information 129Z0~3 1 with a header added thereto to contain connection control information and in accordance with the contents of the header.
Fundamentally, each of the front-end modules functions to determine a destination path for communi-cation information coming from a subscriber line or a trunk line. Specifically, with the use of each inter-module highway having rames occurring at a predetermined period and a plurality of time slots contained in each frame the number of which is determined in predeterminedly ruled relationship with the number of subscriber line or trunk lines accommodated in the front-end module, each front-end module functions to transmit to the highway a block which accommodates the communication information and a header containing a destination front-end module number by loading the block on the time : slots, functions to manage the status of the subscriber line or trunk line by constantly storing an idle/busy status thereof, functions to decide the-idle/busy status of the subscriber line or trunk line, and functions to transmit and receive a result of the decision between : the plurality of front-end modules.
The central module comprises a plurality of time swltches connected to the front-end modules via ~5 the highways, a space switch connected to the time switches, a first status managing memory for monitoring every frame an idle/busy status of a link in association with an incoming highway of the space switch, a second 1~92~i3 1 status managing memory for monitoring in every frame an idle/busy status of a link in association with an out-going highway of the space switch, and a circuit for generating a read address or a write address for each of the plurality of time switches by looking up the first and second status managing memories, in such a manner that a plurality of blocks having the same ~éstination are not switched at the same time.
Further, in the central module of the invention, each incoming highwa~ associated with each incoming front-end module has branches for the purpose of handling both the circuit switching information and packet switching information, one branch being directly con-nected to the time switch and the other being connected lS to a storage circuit, and the storage circuit is selectively used.
By selectively using the storage circuit, the communication information such as voice of which the real-time base processing is required (circuit switching information) can directly be delivered from the incoming highway to the time switch without being passed through the storage circuit, so that real-time base processing can be completed. On the other hand, the storable communication information (storage switching information) is temporarily stored in the storage circuit, so that the storage switching information can be ~witched through the use of the same channel as used for the circuit switching information.

,, -~2~2053 1 The present invention was disclosed by some of the present inventors in an article entitled "A NEW
DISTRIBUTED SWITCHING SYSTEM ARCHITECTURE FOR ~DIA
INTEGRATIoNIl published on June 10, 1987, PROCEEDINGS
OF IEEE INTERNATIONAL CONFERENCE '87 SESSION 11.4.

BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a block diagram showing the overall construction of a switching system of the invention.
Figure 2 is a block diagram showing a configu-ratlon specifying the Fig. 1 system.
Figure 3 is a diagram for explaining an example of a frame format according to the invention.
Figure 4 details a block in the Fig. 3 frame.
Figure 5 explains the contents of a header in the Fig. 4 block.
Figure 6 is a block diagram illustrating an example of a front~end module in the Fig. 1 system.
Figure 7 is a diagram useful in explaining the operation of block set up in the Fig. 6 front-end ~20 module.
: :
:
Figure 8 is a diagram useful in explaining the sequence of call control.
; Figure 9 is~a block diagram illustrating a first embodiment of a central module according to the invention.
; Figure 10 is a block diagram of a space switch shown in Fig. 9.

:: ~ :

129Z~)53 1 Figure 11 is a block diagram of a channel match logic circuit shown in Fig. 9.
Figure 12 is a diagram for explaining the operation of the Fig. ll logic circuit.
Figure 13 is a block diagram of a packet buffer shown in Fig. 9.
Figure 14 is a block diagram of a packet buffer read control logic circuit shown in Fig. 9.
Figure 15 is a block diagram illustrating a second embodiment of the central module according to the invention.
Figure 16 is a block diagram illustrating a third embodiment of the central module according to the invention.
Figure 17 is a block diagram illustrating an exemplary configurati.on of the system.

; DESCRIPTION OF THE PREFERRED EMBODIMENTS
The invention will now be described by way ~ of example with reference to the accompanying drawings.
In describing preferred embodiments of the invention, the overall architecture of a switching system using time-division channels accordlng to the invention will first be outlined for better understanding of the embodiments. Fig. 1 illustrates a fundamental configu-ratlon of the switching system to which a time-division channel arrangement of the invention is applied. As -shown, the heart of the system is ~rovid~d by a central ~ .

~Z92053 module (hereinafter abbreviated as CM) 100 which is connected to front-end modules (hereinafter abbreviated as FMIs) 201 to 208 via highways 220 to 223 and 230 to 233.
The CM 100 is of a self-routing channel type which has no processor. In Fig. 1, the FM's 201 to 204 each provided with an SM (subscriber module) have subscriber interfaces and the FM's 205 to 208 each provided with a TM (trunk module) have trunk interfaces. Thus, the above configur-ation generally provides an exchange. For example, communication information coming from a subscriber line 210 is combined with a destination address at the FM 201 and sent to the CM 100 via the inter-module highway 220.
Fundamentally, the CM 100 has a space switch function and looks up the address described ln the header. If the destination address is for the FM 207, the CM 100 switches to the inter-module highway 232. The FM 207 then transmits the communication information to a trunk line 242 Communication from the trunk line side to the subscriber line side is effected in a similar way. Since ordinary ~ communications of, for example, telephone voice is :: ~
bidirectional, a pair of up-signal modules, for example, from FM 201 to FM 207 and down-signal modules, for :
example, from FM 205 to FM 203 are used in combination.
The number of FM's involved and the ratio between the number of SM's and the number of TM's included in the FN's are determined in accordance with a situation in which the system is placed. If the FM's are all used as TM's, the ;~ ; s~stem of course serves as a trunk exchange.
: ~ :

~ 12 -- -: , lZ9;~0~3 1 It should be understood that the TM' s having trunk interfaces need not always be distributed and they may be concentrated near the CM as illustrated in Fig. 1.
The switching system of Fig. 1 will be described in greater detail with reference to Fig. 2.
The FM as represented by FM 201 comprises a time switch 251, a link interface 252, a control system 253 and a status managing memory 250. Time-division multiplexed communication information issued from a subscriber is inputted to the FM (SM) via a subscriber line and a multiplexer stage, not shown. Under the direction of the control system 253, the time switch 251 rearranges the time-division multiplexed information in accordance with destination modules. The link interface 252 sets ,up blocks each of which is append~d to a header indicative of a destination address and the like to accommodate communication information destined for the same peripheral module. These blocks are carried on time slots and sent to the CM 100.
The CM 100 comprises link interfaces 161 to 16n, time switches 111 to lln, a channel match logic circuit 102, a space switch 103 and time switches 171 to ~17n. The headers of the blocks sent from the FM 201 are read by the link interface 161. The channel match logic circuit 102 looks up header information associated with each of the blocks sent from individual FM's so as to generate addresses which are used for reading ox writing the individual time switches 111 to lln in ~, , ~2!~2(~S3 1 such a manner that a plurality of blocks destined for the same peripheral module can be prevented from coexisting at a time. This operation can be achieved using wired logics only. The time switches 111 to lin respond to the addresses generated from the channel match logic to perform rearrangement of the blocks.
Since the rearrangement is directed to perfect avoidance of collision of a block with another within one frame, that is, to establishment of a non-block condition, the output links of the time switches 111 to lln are operated at a speed which is twice as high as an operation speed of the input links. The space switch 103 performs switching in accordance with destination addresses described in the headers assoclated with respective }5 blocks and sends blocks to one of the time switches 171 to 17n which is connected to a destined FM. The one of the time switches 171 to 17n recovers the original operation speed and transmits the blocks to a highway connected to the destined FM.
The FM as represented by FM 208 comprises a link interface 262, a time switch 261, a control system 263 and a status managing memory 260. The blocks : sent from the CM 100 are s~epara~ed from the headers by means o~ the~link interface 262,~and the communication infor-2~5 mation is written in the time switch 261 in accordancewLth an address which the control system 263 designates on the basis of information described in the header and is again time-division multiplexed so as to be ~29~053 1 transmitted to a trunk line.
Fig. 3 illustrates a frame format on each of the inter-module highways 220 to 223 and 230 to 233.
The frame has a length of, for example, 125~s which is divided into m blocks of fixed length. The frame is headed with a field 300 on which the number of blocks allocated to circuit switching information such as voice and the like requiring real-time base processing is recorded in accordance with individual outgoing I0 highways for which the blocks are destined. Each block is comprised of a header 301 and an information field ~302.
Fig. 4 details a format of one block. The header 301 consists of five areas 311 to 315. Fig. 5 l5 ~shows contents of each area.
; More particularly, data indicative of idle or busy is set in a BC area 311, information indicative of the k1nd of switching or call control information is set in a BI area 312, a receiving FM number is set in a DA area 313, a sending FM number is set in an SA
area 314, and a block number used for a circuit switching call~or a call reference~number used for a store and forward~swltching call is~set;1n a~BN/CN area 315.
The information field~302 has a length of about~s~everal of tens of bytes, for example. The CM
100 relies on only hardware to perform switching on the basis of information described in the header 301.
The number of blocks constituting one physical 1~:92~S3 1 frame can be determined in a manner as will be described below. It is presupposed that n F;~ls each accommo-dating c circuits at the most are involved on either side of the CM, and that the header 301 and the infor-mation field 302 of one block are of h bytes and ibytes, respectively. On the above assumption, the number t of blocks within one frame is so determined as to meet the following condition. The necessary condition prescribes that the number of blocks should not be deficient even when information is sent from a ~sending FM to (n-1) receiving FM's excepting one receiving FM under the worst efficiency condition in which information for only one voice circuit (amounting to one byte) is sent to all of the (n-l) receiving FM's lS and the remainder of 1nformation for {c-(n-1)3 circuits is sent from the sending FM so as to be concentrated on the one receiving FM. In terms of a formula, the above necessary condition is expressed as, ::
: t > (n-l~ + C-(n-l~ (1).

When this condition is satisfied, a status never occurs~ wherein in spite of the presence of idle circuit ~ :or circuits, the information can not be transmitted : ~ because of a deficiency in the number of blocks.
On the other hand, thanks to the addition of the header, the overhead o of an inter-module highway can be expressed as, - i6 -1~53 t~th+i~ (2~-c 1 Equation (1) indicates that the longer the length i of the information field, the smaller the number t of requisite blocks becomes and equation ~2) on the other hand indicates that as either of i and t increases, the overhead o is increased. Accordingly, there exists an optimum value of either of i and t which can minimize the overhead o and the optimum value can result from a trade-off between equations (1) and (2).
By determining the number of blocks in this manner, a block necessary for an FM to communicate can be retained without fail as far as that FM has an idle circuit. Consequently, the FM need not monitor the idle/busy status of a block.and can perform resource management by solely monitoring the idle/busy status : 15 of the circuit.
The construction of each of the FM's 201 to : ~ 208 shown in Fig. 1 will now be described in greater :~ ~ detail.
: In the following description, a call typically : :;20 represented by telephone voice,of which periodicity and~real-time base processing a~e required,will be referred to as a circuit swltching call and a call, ;: wh1ch has no periodicity but has a so-called burst property :and which does not stringently require the real-time : 25 base processing,will be rèferred to as a storage :: switchlng call. The meaning of these calls is not ,, 1292~53 1 coincident with that of calls handled by the existing circuit exchange and packet exchange and is not limited thereto.
Fundamentally, the FM comprises, as shown in Fig. 6, a multiplexer stage 402, a block set-up unit 403, a packet buffer 404, a process/control system 405 and a memory system 406. The process/control system 405 corresponds to the control system 253 of Fig. 2 and the memory system 406 similarly corresponds to the memory 250. The block set-up unit 403 corresponds to the time switch 251 and link interface 252 in combination.
: The FM has input/output lines as represented by an inter-module highway 400 and a subscriber or trunk line 401 and the direction of the input/output lines depends on whether the FM is located on the transmitting side or on the receiving side.
A signal coming from the subscriber or trunk line 401 passes through the multiplexer stage 402 so : as to be inputted to the block set-up unit 403 directly in the case of a circuit switching call (C) or via the buffer 404 ln the case of a storage switching call : (P). At the block set-up unit 403, communicated information is accommodated in blocks in a manner to be:described later and then is transmitted to the inter-~ :25 module highway 400.~ All of the information necessary for : switching processing (various kinds of translation information, resource managing information and the like information) is stored in the memory system 406, , . . .

~Z~312~3 1 and the process/control system 405 having a processor performs a switching function typically including call control.
A circuit switching call can be accommodated 5 in blocks in a manner to be described below with reference to Fig. 7 which is illustrative of block set-up operations.
In the case of a circuit switching call (C), communication information of the same information amount occurs periodically. For example, in PCM coded voice, 8 bits of information occur every 125 ~s. Accordingly, a~
desired block, for example, block No~ 2 may be selected for one circuit call, for example, B and desti-nation and communication information of the one circuit lS call may be accommodated in the header and information field of the block No. 2. The term "destination" herein corresponds to a destination outgoing highway, i.e., a receiving FM number. Once a block has been selected, the location of the selected block is invariably used every period, i.e., every physical frame. If the amount of communication information occurring every period ;~ is too large to be accommodated in one block, two or more blocks may be used. Conversely, if communication information for one circuit call is accommodated in 25 one block leaving behind a space area, communication ; lnformation for a plurality of circuit calls having the same destination, for example, circuit calls A and B
may be acco~modated in the information field of the ,, -- 1 9 --~, 1 same block, for example, block No. 1~
A switching call which has ~ varying amount of information occurring every period is not treated as a circuit switching call but is treated as a storage switching call to be described below.
A storage switching call (P) does not stringently require real-time base processing, as compared to the circuit switching call. Therefore, the circuit switching call (C) has a preference in accommodating information in the block. Thus, blocks are initially allocated to the circuit switching ra (c) and thereafter, the remaining unoccupied blocks are used to accommodate the storage switching call (p).
Since the number of calls within the circuit switching call and the amount of information for each circuit call are not fixed when measured over a long period of time, the amount of communication information for a storage switching call which can be accommodated in the block and transmitted at a time point is not fixed. Accordingly, for waiting for packets typically used in storage switching, a FIFO buffer (packet~bufer 404 shown in Fig. 6)~ is provided.
Since the storage switching call (P) does away with the concept of a frame, packets are sequentially ~25 aocommod~ated, beginning with the leading packet in the FIFO buffer, in the information field of an idle block, - for example, block No. 3 which remains unoccupied after the allotment of the circuit calls to blocks, so that 129~0S3 1 communication information for the packet, inclusive of such information as a packet header added pursuant to the protocol, can be accommodated in the block No. 3.
If the length of one packet exceeds the length of the information field of one block, the one packet may be divided so as to be accommodated in a plurality of blocks, for example, blocks Nos. 3 and 4~ In this case, the header of each block is of course described with the same destination.
In the case of the storage switching call, a plurality of calls will not be contained in one block.
Thus, even when the length of one packet is shorter than the length of the information fieId of one block and even when one packet is divided so as to be accommo-dated in a plurality of blocks and a block accommodating :
the~ final division of that packet has the information field which is almost unoccupied, another storage switchLng call of the same destination can not be accommodated in the same block together with that packet. The block for accommodating the storage ; swltching call is not always located at the same position in~each frame. For example, when a circuit switching : ~ : :; : :
call~ends and a block which has been dedicated to the circuit switching calI becomes unoccupied, this block :
is used,~in the subsequent frame, for accommodating a storage switching call being stored in the FIFO buffer at that time point.

: :
; ~ ~ As regards the circuit switching call, circuit :: :

:
, 1 calls must be switched with a minimized predetermined delay time. In this embodiment, when a call i5 origi-nated, a channel path is set and a block number to be used every period is initially retained in the following manner. More particularly, as shown in Fig. 8, when an SM (one of the FM's 201 to 204 in Fig. 1), for example, SM 201 d~tects an originating call, it determines a route by analyzing a selection number such as a dial number. Since a determined outgoing route generally accommodates a plurality of TM's 205 to 208 shown in Fig. 1, a desired onej~for example, TM 207 is selected ~; among them.
Various kinds of selection algorithm~ are conceivable. Especially, considering that the F~'s on the ~15 transmitting side do not communicate with each other, a : :~ desirable algorithm is one in which different FM's on transmitting side preferably select different FM's on the receiving side. Thus, determination of the algorithm depends on a situation in which the system is placed.
~20 For example, especially where a specified SM frequently communicates through a~specified path, the specified SM~may always select a specified~ TM and the other SM's :
must not select the specified TM.

After selection of the TM 207, a call set-up 25 ~signal is sent to the TM 207. This may be done using a call~control information block in this embodiment, , though another signal line may otherwise be used.

Described in the information field of this block are .

~2~20S3 1 a selection number, a signal speed and a used block number. By consulting the information, the TM 207 can recognize which block corresponds to the originating call and how many and which bits of information in the corresponding block correspond to the originating call.
If a plurality of calls are contained in one block, the TM 207 can also recognize which call corresponds to that originating call and how many and which bits of information in the corresponding call correspond to that originating call. It should be noted herein that as as algorithm for accommodating a plurality of calls destined for the same path in one block in order to minimize the overhead of the header, a kind of generally called group switching may be used.
In the TM 207 which is in receipt of the origi-nating call signal, the process/control system 405 shown in Fig. 6 looks up the status managing memory such as 260 in Fig. 2 included in the memory system 406 to determine the idle/busy status of circuits accommodated in the TM 207. If the status is idle, one of the idle circuits is acquired, the circuit status managing memory 260 is rewritten and thereafter a response signal is returned. The response signal is transmitted from a transmitting TM, for example, TM 205 in Fig. 1 which is paired with the receiving TM 207, by using a call control information block and is received by an SM, for example, SM 203 which is paired with the transmitting SM 201. Described in the response signal : ~

129~53 1 are a used block number and a signal speed. The recep~ion of the response signal by the SM 203 completes the path setting.
In this manner, each of the FM's 201 to 208 in Fig. 1 can acquire a circuit and retain a block used for communications without assistance of the CM 100 in Fig. 1 by merely monitoring the status of circuits accommodated in each FM, determining the idle/busy status and indicating a result of thc decision.
In contrast to the circuit switching call, storage is permitted for the storage switching call.
Accordingly, the acquisition of an outgoing circuit is not always required and the path setting as needed for the circuit switching call is not performed precedently.
~he FM applies protocol procedures necessary for packet switching processing to packets coming from the subscriber line or trunk line, and thereafter accommodates the packets in unoccupied blocks in sequence of arrival and performs the switching operation, as described previously.
When unoccupied blocks are acquired, storage of packets is effected by, for example, a transmitting FM. -When an outgolng circuit is acquired, storage of packets is effected by, for example, a receiving FM.
As described above, the number of blocks for accommodating the communication information for the storage switching call and the position of the blocks within a frame are variable. However, commu-1292(~53 1 nication information for a plurality of calls is not accommodated in one block. Accordingly, in place of the used block number described in the header af a in the case of the circuit switching call, a call number for distinguishing calls from each other is described in the header in the case of the storage switching call.
Thanks to the channel match logic circuit to be detailed later, when a pair of transmitting and receiving FM's are viewed, the sequence of blocks transmitted and received between the paired FM's is not rearranged.
Fig. 9 illustrates a fundamental configuration of the CM lO0 shown in Fig. 1 which is the key part of the present system. In association with _ FM's on ~ the transmitting side, not shown, and n inter-module highways 141 to 14n, n time switches 111 to lln are provided. The outputs of the time switches are connected to n inputs of space switch 103, the space switch 103 having n outputs respectively connected to n F-rl~s on the receiving side, not shown, via n ~inter-module ~; ~20 highways 151 to 15n.
Selectors 13l to 13n are adapted to selectively transmit circuit switching call blocks and storage switching call blocks in such~a manner that the former blocks are directly connected to the time switch lll to lln, respectively, and the latter blocks are connected thereto via packet buffers 12l to 12n.
Each of the packet buffers 12l to 12n is controlled by a packet read control logic circuit lOl.

123~3 1 Each of the time switches 111 to lln is controlled by the channel match logic circuit 102. Either of the packet read control logic circuit 101 and channel match logic circuit 102 may be realized with wired logic.
The space switch 103 is a so-called self-routing switch which performs self-controlled switching in accordance with a destination address described in the header of each block and it may take various configu-rations of which one is exemplified in Fig. 10. The configuration shown in Fig. 10 is simple wherein selectors 511 to 51n are provided in association ~ith individual destination FM's, and switching address generation circuits 521 to 52 responsive to the header information generate switching addresses used to switch the selectors 511 to 51n~ Selection by the selectors 511 to 51n can be performed in timed relationship with the addresses from the circuits 521 to 52n by means of re-timing circuits 501 to 50n.
Fundamentally, the CM has the above space -switch function. With the simple space switch, however, the CM becomes unable to switch when receiving blocks having the same destination from a plurality of differ-ent FM's at a time. The time switches 111 to lln are adapted to rearrange t1me positions of the blocks in such an event. The time switches 111 to lln are controlled by the channel match logic circuit 102 which will be detailed below.
The channel match logic circuit is illustrated , . ~
~-- t ;-, ' ,:

~92~3 l in block form in Fig. 11 along with the time switches 11l to lln and space switch 103 which have been explained with reference to Fig. 9.
The channel match logic circuit 102 comprises an address multiplexer 601, a primary link managing memory 602, a secondary link managing memory 603 and an address calculator 604. The "primary link" referred to herein corresponds to the incoming link of the space switch 103 and the "secondary link" to the outgoing link of the space switch 103.
The headers (301 in Figs. 3 and 4) of infor-mation transmitted through the highways are read in ; ~advance of the time switches lll to ll~ and multiplexed at the address multiplexer 601. Of the contents of the header, the sending address 314 in Fig. 4 is used to read the primary link managing memory 602 and the destination address 313 in Fig. 4 is used to read the secondary link managing memory 603. The idle/busy status of each block on the primary link is written in the primary link managing memory 602 in association with the~xespective FM's and the idle/busy status of each block on the secondary~ link~ is written in the secondary ; link managing memory 603~in association with the respective FM's.
: ~ : ` : :: ~:
~ ~ ~ To set up non-block channels, the operation speed of the space switch 103 is doubled. As a result, :
the num er of blocks prevailing in the space switch is twice the number o incoming blocks inputted at ~2~3 1 a cycle of one frame.
With the above construction, it is possible to know which block on either of the primary link and the secondary link is idle at a time point within a frame.
For more details, reference should be made to Fig. 12. Blocks coming from an i-th incoming FM are seen from Fig. 12 as destined for a j-th outgoing FM.
with "1" indicating a busy block and "0" indicating an idle block.
~ The address calculator 604 responds to an i-th sending address and a j-th destination address to read the contents of the primary link managing memory 602 and secondary link managing memory 603.
~ The read two contents of the memories are ORed to determine idle blocks common to the two links.
~ An address of an idle block in the closest positional relationship with the heading block within the frame is used as a write address to be written in the time switch.
At the used position, ~0~ is rewritten to "1" .
~ And th~s information ("0" or "1"~ is fedback to the primary link managing memory 602 and secondary link managing memory 603.
In this manner, the incoming blocks are random-written in each of the time switches 11 to 11 on the 1 nbasis of the write address and concurrently the primary ~ ,~
,'' ~2~2~)S3 1 link managing memory 602 and secondary link managing memory 603 are rewritten until a processing for sne frame has been completed. Thereafter, the time switches are sequentially read and the blocks thus read are sent to the space switch 103, thereby ensuring that the blocks can be prevented from colliding with each other within the space switch 103. In the foregoing description, the time-switches 111 to lln are assumed to be of a so-called double buffer configuration having 10 ~a write surface and a read surface which are used alternately. Further, in place of random-write and ; sequential read as described, sequential write and random-read may be used to obtain a configuration which functions similarly.
The circuit switching call can conveniently be controlled by the channel match logic circuit as described previously. In the case of the circuit swltching call, the path setting is initially effected to retain the outgoing circuits as described ~20 above and therefore there is no possibility that blocks wlll arrive having the same destination which exceed :: : :
the circuits in number. Accordingly, the sequence of blocks can be rearranged within a frame without fail.
~ ~ In the case of the storage switching call, on ; the other hand, no path setting is effected prior to ~ communications and communication information for the :: :
~ storage switching call is accommodated in the idle : ~ , ~ - 29 -123~0~3 1 blocks unoccupied by the circuit switching call as much as possible for the idle blocks to accommodate~
This leads to the fact that calls of the same desination passibly may be allocated unlimitedly to idle blocks so long as such idle blocks exist and it is impossible for the calls to be rearranged perfectly within one frame so as to prevent them from colliding with each other. The channel match logic circuit, however, can execute only operations in a unit o~ a frame, To cope with this problem, as shown in Fig. 9, there are provided the packet buffers 121 to 12n and the packet buffer read control logic ~ircuit 101.
The packet buffers 121 to 12n will now be detailed with reference to Fig. 13 and the packet buff~r read control logic circuit 101 with reference to Fig. 14.
It is assumed in Fig. 13 that blocks accommo-dating a packet switching call appear on, for example, the first incoming highway 141 and arrive at a register 701 and a selector 131. When recognizing from the header information for the blocks that the blocks are for the storage switching call, the register 701 switches the connection of the selector 131 to a packet buffer side 121 and issues a signal C to the effect that the current switching call is not a circuit switching call.
The register 701 reads a destination address DA in the header. A distributor 702 is set in accordance with the destination address DA so that the blocks are stored in one of buffers 711 to 71n which corresponds ~2~

1 to or is associated with the destination address.
The destination address DA is on the other hand decoded by a decoder 703 and used to count up one of up/down counters 721 to 72n which corresponds to or is associated with the aforementioned buffer. Thus, the up/down counters 721 to 72n count the number of blocks stored in the buffer 711 to 71n, respectively. The stored block number is supplied to a priority logic circuit 704 via respective gates 731 to 73n' The function of the gates 731 to 73n will be descrlbed later.
The priority logic circuit 704 delivers a counter number, that is, a number indicative of a buffer which stores the maxlmum stored block number among inputted n stored block numbers. The maximum number is decoded by a decoder 705 which~is operated in timed relationship with the signal C to issue a read clock RCK to only the buffer selected by the signal C. In accordance with the read clock RCK, that buffer storing the blocks the number of which is maximal at that time point is read. The selector 131 is also activated by ; ~ the signal C to send the blocks read out of the buffer to the tlme switch 111. ~Concurrently, the read clock RCK counts down the up/down counter in question selected among the up/down counters 721 to 72n~ The read clock RCR also counts the contents of selected one of counters 741~to 74n~ Each of the counters 741 to 74n counts the number CNT of blocks actually read from each of ; ~

12~053 l the corresponding or associated buffers 711 to 71n.
The counters 741 to 74 are reset by a reset signal RST
in synchronism with the heading of a frame.
The priority logic circuit 704 is employed herein for illustration purpose only and conceivably, the same function may be achieved in various ways including a simple way to select buffers according to a sequence of numbers and a way to select buffers -on the basis of random numbers.
Turning to Fig. 14, each of the registers 8~1 to 80n detects the heading of a frame on each of incoming highways 14l to 14n to produce the reset signal RST and fetches the number of blocks for circuit switching call, which follow the heading and which are destined for 15 each destination outgoing highway, into respective adders 811 to 8ln-in accordance with respective desti-natlons. The adders 181 to 18n are provided in ; association with the destinatlon outgoing highways~
~respectively. Each of the adders 811 to 81n adds to~gether the number of the blocks for circuit switching call which come from respective incoming highways and which are destined for the corresponding destination outgoing highway, and besides calculates the permissible num~er of blocks for store and forward switching call whioh~are destined for respective destinatlons on the basis of a difference between the sum of the number of the~blocks for circuit switching call and the ~.aximum number of blocks which is permitted to be accommodated ~, f ii, s-~

1 in the frame. Each of subtracters 821 to 82n constantly subtracts n from a calculated value delivered out of each of the adders 811 to 81n. This provides a way to prevent the permissible number from being exceeded even when n packet buf~ers 121 to 12 request, at a time, blocks for packet switching call which are destined for a specified destination. To this end, various different ways are conceivable including a way to deliver blocks to packet buffers of lower numbers.
Each of adders 841 to 84n receives output numbers from the aforementioned counters 741 to 74n which are other counters corresponding to n surfaces of the incoming highways adapted to count the number of blocks which are actually read. Thus, each of the adders 841 to 84n adds together the actual number of blocks which come from respective incoming highways corresponding to each destination outgoing highway.
Each of comparators 831 to 83n compares an output value from each of the subtracters 821 to 82n wlth an output value from each of the adders 841 to 84n. Thus, the comparators 831 to 83n constantly compare the permissible number of blocks for storage switching call wlthin the frame with the number of actually read blocks. When the permissible numb:er is not exceeded, 25~ the comparators 831 to 83n produce output signals OK of "1". The gates 731 to 73n shown in Fig. 13 are responsive to the output signals of the comparators 831 to 83n to inhibit the input to the priority logic circuit 704 in 129~053 l respect of a destination number for which the permissible number is exceeded, so that after the inhibition, no block may be read out of a buffer corresponding to the destination in question.
Although in this embodiment the number of blocks for circuit switching call which are destined for respective destination outgoing highways is obtained by reading the specified field using the resistors 80l to 80n, the number of blocks may be obtained by counting calls in accordance with individual destinatious using the contents of the control information blocks used for call-setting.
As is clear from the foregoing description, either of the packet buffer read control logic circuit lO1 and each of the packet buffers l2l to l2n may be realized with wired logic.
In the foregoing, one embodiment of the time-divis1on channel arrangement of the invention has been set forth and it has been described that an integrated ;20 switching system can be constructed which is a star-type distributed switching system wherein the CM placed in the heart is surrounded by distributed FM's and which is able ~to 1ntegratedly handle the circuit switching information ~ ; ~ and the storage switching information. However, the ; ~ 25 ~invention is in no way limited to the system according to the embodiment set forth so far.
Second and third embodiments of the integrated switching system capable of integratedly handling circuit - 3~ -, .

~2~()53 1 switching information and packet switching information will now be described.
The framework of the second embodiment is such that packet buffers corresponding to respective destination FM's are provided in a CM in associatiOn with respective incoming FM's and each of the packet buffers is connected to each destination via a bus circuit. In this embodiment, the channel match logic circuit as described in connection with the first embodiment is operated for only the circuit switching information.
rrhe framework of the third embodiment is such that the channel match logic circuit is operated for both the circuit switching information and packet switching information. In the case of packet switching, blocks can not all be rearranged within one frame in some instances. Therefore, in association -with respective incoming FM's, buffer memories are provlded for accommodating some blocks which have been invalidated for rearrangement. However, in order to process the circuit switching information with priority, a frame has a header field, whéreby the number of blocks CarryLng the circuit switching in~ormation is communi-~ .
cated from respective incoming FM's to the channel match logic circuit, thereby making it possible to steadily ` process~the blocks carrying the circuit switching nformation without resort to buffers.

~ ~ In the second embodiment, since the packet ::: ~,:
~ - 35 -" 12~0~3 1 buffers corresponding to respective destination FM's are provided in association with respective incoming FM's, the packet switching information can be assorted during buffering. Subseqently, the packet switching information in buffers associated with the respective incoming FM's and destined for the same destination is multiplexed by the bus circuit so as to be sent to the same destination FM.
In the third embodiment, the packet switching information is treated in the same manner as the circuit swltching information. However, in contrast to the circuit switching lnformation, the packet switching information is not assisted by the preceding acquisition of an idle circuit and in the case of the packet switching information, blocks having the same desti-nation are sometimes concent~ated. The channel match logic circuit is effectiveIy operated for the circuit switching information to ensure that blocks destined ~for the same destination can be rearranged so as not to collide with each other at a time point. In contrast, when in the case of~the packet switching information, blocks having the same~destination which are concent-, rated and unlimited in number arrive, there is a possibility that the blocks can not all be rearranged :: , , 25 or avoidance of collision within the frame Sincethe packet switching information is permitted to be ; delayed to some extent, blocks invalidated for rearrange-ment are returned to the buffer so as to be processed 12~9~053 1 during the subsequent frame cycle. The packet call is of a burst-like communication form and a probability that blocks of the same destination are concentrated in sequential frames is low. merefore, after several repetitions of the above returning operation, the procedure can be advanced.
Fig. 15 illustrates a second embodiment of a circuit/packet integrated channel arrangement. This arrangement corresponds to Fig. 9 illustrating, in block form, the arrangement of the CM according to the first embodiment. The integrated channel arrangement of the second embodiment comprises time switches 111 to lln, packet buffers 1211 to 121n, bus circuits 181 to 18n, a channel match logic circuit 102, a space switch 103, and time switches (speed conversion buffers) 17 to 17n. When blocks each having a header described with destination PM number and indication for distinction between circuit switching and packet switching as well as information arrive at the CM via one of incoming highways 141 to 14n, for example, the first highway 141, circuit switching information and packet switching information are dlstributed to the time switch 111 and the packet buffer 1211, respectively. Switching for the circuit switchlng information has already been ~25 described. The packet buffer 121I has destination branches and the incoming blocks are subjected to buf~ering in accordance with the destinations. The above distribution is effected for each highway and blocks ",: .

~2~2~;3 1 in the respective buffers destined for the same desti-nation are multiplexed by the corresponding one of the bus circuits 18l to 18n. A multiplexed signal is carried on idle time slots, unoccupied with circuit switching information, on one o~ the outgoin~ highways lS
to 15n. In this embodiment, the circuit switching information passes through the space switch and the packet switching information passes by the bus circuits.
With the relatively simplified logical circuits, the multiplexed packet switching information can be trans-mitted to the outgoing highway with high efficiency.
Turning to Fig. 16, a third embodiment of a circuit/packet integrated channel arrangement will now be described. Particularly, Fig. 16 illustrates, in lS block form, a CM arrangement as in the case of Figs. 9 and 15. In this embodiment, first packet buffers 1221 to 122n and second packet buffers 1231 to 123n substitute for the packet buffers 1211 to 121n and bus circuits l81 to 18n of Fig. 15. As in the case of the Fig. 9 embodiment, blocks carrying packet switching infor-mation, like blocks for circuit switching information, are sub~ected to switching by~means of time switches to lln and a space switch 103. Due to the fact that the clrcuit switching information is preferentially processed and so the packet switching information is sometimes required to be delayed, the first packet buffers 1221 to 122n are provided. In order that the packet switching information can undergo switching , , -~ 2~9~0S~

1 similarly to the circuit switching information, it is necessary for a channel match logic circuit 102 to effectively operate also for the packet switching information. In the case of the circuit switching the number of blocks having the same destination is limited but in the case of the packet switching~ blocks arrive unlimitedly so long as idle blocks are available.
Accordingly, even with the channel match logic circuit 102 operating to prevent blocks of the same destination from colliding with each other at a time point, the blocks can not all be rearranged in some instances.
The second packet buffers 1231 to 123n are adapted to accommodate blocks which have been invalidated for rearrangement and overflown. As described previously, I5 the channel match logic circuit 102 has been informed, by the heading of a frame, of the number of blocks carrying the circuit switching information within the frame, and it can permit the circuit switching infor-mation to be processed preferentially and only the packet switching information to be bypassed. Once ;~ stored in the second packet buffers 1231 to 123n, the bypassed blocks are immediately returned to positions near the heading of the first packet buffers 1221 to 122n. This operation repeats itself until channel matching succeeds. This embodiment is advantageous in that the space switch can be adapted for the integrated oircuit/packet information and packet buffers in association with respective destinations can be , ,"

1 dispensed with~
Thus, this embodiment can materialize a circuit/packet integrated CM.
As is clear from the foregoing, the CM can be constructed using wired logics only and can be a passive module which does not need any control processor.
Referring to Fig. 17, there is illustrated an example of system configuration. This configuration intends to distribute or disperse load and danger by the provision of a plurality of CM's 1001 and 1002.
Since the CM's 1001 and 1002 are passive modules having no processor for call processing, the distribution of load and the disper,s~l of danger can be realized,with ease. The information from individual incoming FM's 2001 to 2004 can reach individual outgoing FM's 3001 to 3004 via either of the CM's 1~01 and 1002 and conse-quently, in the event of failure of one CM, the operation can continue via the other CM. Unless the valid CM is overloaded, no trouble occurs.
According to the embodiment of Fig. 17, each ; FM is required to,.monitor only its own circuits -: and the concentrated resource management is not needed, thereby eliminating a bottleneck which would~otherwise be caused in the processing by the common unit, i.e., the CM so as~to improve throughput of the overall switching system. The high throughput of the overall switching system can also be attributable to the fact that while each FM is an independent ~: ~
~ 40 -~ ;

... .... . . . .

i3 l distributed module which has a processor of its own and therefore can fully take care of the call processing, the common unit or CM has full wired logic which has no call processing processor and can do away with a bottleneck caused by the throughput of ~ processor.
Further, the CM can fulfill itsel in switching without assistance of a processor and a switch holding memory will not leave behind any aging influence even if becomes faulty intermittently and besides will remain almost unaffected even if a fault occurs in any one of the FM's, thereby giving rise to realization of a highly reliable distributed type switching system.
It will therefore be appreciated that the distribution of load and the dispersion of danger can ~15 lead to realization of a high-throughput and highly ~reliable distributed type switching system.
In summary, the present invention has the following advantages.
The star-type distributed switching system in~which the FM's are distributed around the CM in the heart, especially, the circuit/packet integrated distributed type switching system capable of integrally handling circuit switching and pack~et switching can be rea11zed. Spec1fical1y, since the CM has no call processing function and fundamentally, it can be realized with a wired logic, thus preventing the ~:~: : : :
~ throughput of the system from being limited by a ;~ bottleneck which would otherwise be caused by a J!~ ~ --41 j -~ ' t ~

~2~9~0~3 1 processor. Further, the distribution of a plurality of CM's is easy to achieve.
Blocks of identical format are used to switch the circuit switching information and the packet switching information to thereby improve the exchange from the economical standpoint. Multi-dimensional distribution and high-speed wide b nd services can be offered integratedly to subscribers. For the circuit switching information, switching is effected preferentially, leading to advantages that delay time is invariable and absolute delay time is minimized. More particularly, the circuit switching call such as voice can be switched within invariable and minimal delay time while the storage switching call having burst property can be switched using the same channel. In addition, all time slots unoccupied by the circuit switching call can be allocated to the storage switching call to reali2e a highly efficient economical channel.
The channel is of a full wired logic which is not dominated by the throughput of a processor or the like factor and can readily have throughput complying with the scale of the system. Processings at most parts of the system can be effected in distributing and parallel relationship with respective highways and the cycle time required for processing can therefore be reduced.

. . ...

Claims (23)

1. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules axe connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways information in frames occurring at a predetermined period, each frame having a plurality of blocks.

2. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways information in frames occurring at a predetermined period, each frame having a plurality of blocks;
wherein each of said front-end modules comprises:
means for determining a destination path for communication information coming from the subscriber line or the trunk line;
means for transmitting a block which accommodates the information and a header containing a destination front-end module number to a highway connected with said central module by loading said block on the time slots on said highway, said transmission of a block being periodic for telephone voice information; and status managing means for storing idle/busy status of the scriber line or the trunk line.

3. A switching system according to claim 2 wherein said front-end module further comprises:
means for determining the idle/busy status of the subscriber line or the trunk line; and means for transmitting and receiving a result of said determination between said plurality of front-end modules via said highway.

4. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said central module comprises:
(a) a plurality of time switches connected to said plurality of front-end modules;
(b) a space switch connected to said plurality of time switches; and (c) means for generating a read address or a write address for each time switch from header information for each block incoming from each front-end module, in such a manner that a plurality of blocks having the same destination do not coexist at the same time;
wherein said address generating means comprises:
(a) a first status managing memory for monitoring in every frame idle/busy status of a link in association with an incoming highway of said space switch;
(b) a second status managing memory for monitoring in every frame idle/busy status of a link ln association with an outgoing highway of said space switch; and (c) a circuit for generating the read address or the write address for each of said plurality of time switches by looking up said first and second status managing memories.

5. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said central module comprises:
incoming highways and outgoing highways, either of each incoming highway and each outgoing highway having a plurality of time slots carrying blocks;
primary time switches connected to said incoming highways;
secondary time switches connected to said outgoing highways;
a space switch for interconnecting said primary time switches and said secondary time switches;
a group of buffer memories being in association with respective outgoing highways, each buffer memory and each primary time switch being in multiplexed connection with each incoming highway; and bus circuits for bus-coupling outputs of said buffer memories in association with respective outgoing highways and multiplex-connecting the outputs and each primary time switch to each corresponding outgoing highway.

6. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein each central module comprises:
incoming highways and outgoing highways, either of each incoming highway and each outgoing highway having a plurality of time slots carrying blocks;
primary time switches connected to said incoming highways;
secondary time switches connected to said outgoing highways;
a space switch for interconnecting said primary time switches and said secondary time switches;
first buffer memories each having the input connected, together with each primary time switch, to each incoming highway and the output connected to the associated primary time switch; and second buffer memories each having the input multiplex-connected to the output of each first buffer memory, together with said associated primary time switch and the output connected to the associated first buffer memory to permit transfer information in unit of block therebetween.

7. A switching system comprising:
a plurality of incoming highways and a plurality of outgoing highways, either of each incoming highway and each outgoing highway consisting of a plurality of blocks each containing connection control information and communication information;
switching means for switching communication information coming from said plurality of incoming highways and trans-mitted to said plurality of outgoing highways by rearranging said plurality of blocks spatially and on time axis;
a plurality of storage means provided in association with said plurality of incoming highways; and a plurality of selection means provided in association with said plurality of incoming highways, each selection means having a first input directly connected to the associated incoming highway and a second input connected to the associated storage means, each selection means selectively connecting said first and second inputs to said switching means.

8. A switching system according to claim 7 wherein the connection control information in each block has in part information for distinguishing whether the communication information in the block requires real-time base processings or not and said system further comprises means for identifying the distinguishing information to control said blocks such that some of said blocks accommodating communication information requiring the real-time base processings select the first input of said selection means and some of said blocks accommodating communication information not requiring the real-time base processings select the second input of said selection means.

9. A switching system according to claim 7 wherein each of said plurality of storage means comprises:
a plurality of buffer memories provided in association with destination outgoing highways to which said blocks are to be switched;
means for writing the block in one of said buffer memories in accordance with the connection control information accommodated in that block; and means for selecting any one of said buffer memories and reading the block stored in the selected buffer memory.

10. A switching system according to claim 7 wherein each of said plurality of incoming highways is of a frame having a plurality of blocks and a field recorded with the number of blocks within the frame which are destined for respective destination outgoing highways, and a common control circuit is provided in common to said plurality of incoming highways, said common control circuit including means, connected to each of said plurality of incoming highways, for reading the field in each frame on each incoming highway, and means responsive to the read number of blocks destlned for respective destination outgoing highways to generate a signal for controlling read of each storage means.

11. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line;
each front-end module including means for determining the idle/busy status of subscriber line or the trunk line and means for transmitting and receiving a result of said determination between said plurality of front-end modules via inter-module highways;
at least one central module for interconnecting said plurality of front-end modules in star-type fashion and for switching user information between said front-end modules in accordance with connection control information added to said information; and said inter-module highways for connecting said plurality of front-end modules to said central module, each inter-module highway having frames occurring at a predetermined period and a plurality of time slots contained in each frame.

12. A switching system comprising:
a plurality of front-end modules each adapted to perform switching processing in association with subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block having a fixed length, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways information in frames occurring at a predetermined period, each frame having a plurality of blocks;
wherein each of said front-end modules comprises:
status managing means for storing idle/busy status of the subscriber line or the trunk line.

13. A switching system comprising:
a plurality of front-end modules each adapted to perform switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways information in frames occurring at a predetermined period, each frame having a plurality of blocks;
wherein each of said front-end modules comprises:
means for determining a destination path for communicating information coming from the subscriber line or the trunk line;
means for transmitting a block which accommodates the information and a header containing a destination front-end module number to a highway connected with said central module by loading said block on the time slots on said highway; and status managing means for storing idle/busy status of the subscriber line or the trunk line.

14. A switching system comprising:
a plurality of front-end modules each adapted to perform switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways said blocks;
wherein each of said front-end modules comprises:
means for determining a destination path for communicating information coming from the subscriber line or the trunk line;
means for transmitting a block which accommodates the information and a header containing a destination front-end module number to a highway connected with said central module by loading said block on the time slots on said highway, said transmission of a block being periodic for telephone voice information; and status managing means for storing idle/busy status of the subscriber line or the trunk line.

15. A switching system comprising:
a plurality of front-end modules each adapted to perform switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block having a fixed length, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein each of said front-end modules comprises:
status managing means for storing idle/busy status of the subscriber line or the trunk line.

16. A switching system comprising:
a plurality of front-end modules each adapted to perform switching processing in association with a subscriber line or a trunk line;
each of said front-end modules having means for transmitting on inter-module highways user information to be delivered between said front-end modules in a unit of a block having a fixed length, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling switching, and comprising status managing means for storing idle/busy status of the subscriber line or the trunk line; and at least one central module for interconnecting said plurality of front-end modules via said inter-module highways in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of said block, which said switching is controlled by said connection control information of said headliner in said block.

17. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways said block;
wherein each of said front-end modules comprises:
means for determining a destination path for communicating information coming from the subscriber line or the trunk line;
means for transmitting a block which accommodates the information and a header containing a destination front-end module number to a highway connected with said central module by loading said block on said highway; and status managing means for storing idle/busy status of the subscriber line or the trunk line.

18. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including call identifier for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways said block;
wherein each of said front-end modules comprises:
means for determining a destination path for communicating information coming from the subscriber line or the trunk line;
means for transmitting a block which accommodates the information and a header containing a destination front-end module number to a highway connected with said central module by loading said block on said highway; and status managing means for storing idle/busy status of the subscriber line or the trunk line.

19. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways said block;
wherein each of said front-end modules comprises:
means for determining a destination path for communicating information coming from the subscriber line or the trunk line;
means for transmitting a destination front-end module number in accordance with each block to said central module;
and status managing means for storing idle/busy status of the subscriber line or the trunk line.

20. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways said block;
wherein each of said front-end modules comprises:
means for transmitting a destination front-end module number in accordance with each block to said central module;
and status managing means for storing idle/busy status of the subscriber line or the trunk line.

21. A switching system comprising:
a plurality of front end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connection control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways said block;
wherein each of said front-end modules comprises:
means for determining a destination path for communicating information coming from the subscriber line or the trunk line; and status managing means for storing idle/busy status of the subscriber line or the trunk line.

22. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including connected control information for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways said block;
wherein each of said front-end modules comprises:
means for transmitting a block which accommodates the information and a header containing a destination front-end module number to a highway connected with said central module by loading said block on said highway; and status managing means for storing idle/busy status of the subscriber line or the trunk line.

23. A switching system comprising:
a plurality of front-end modules each adapted to perform a switching processing in association with a subscriber line or a trunk line; and at least one central module for interconnecting said plurality of front-end modules in star-type fashion, and including means for switching user information to be delivered between said front-end modules in a unit of a block, each block accommodating information as a part of the user information and a header appended thereto, said header including call identifier for controlling said switching;
wherein said front-end modules are connected to said central module via inter-module highways, each front-end module having means for transmitting on said inter-module highways said block;

wherein each of said front-end modules comprises:
means for determining a destination path for communicating information coming from the subscriber line or the trunk line; and status managing means for storing idle/busy status of the subscriber line or the trunk line.