JP3399994B2 - ATM switch and signal synchronization control method in ATM switch - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention controls a plurality of connections (voice connection, video connection, data connection, etc.) with one call when realizing a connection service using a multimedia terminal connected to an ATM switch. The present invention relates to an ATM switch and a signal synchronization control system in the ATM switch . There is an increasing need for multimedia communication including not only voice communication and data communication but also moving image communication. As a means for realizing such broadband communication, an asynchronous transfer mode (Asynchronous Trans
B-ISDN (Broadb) based on fer mode (ATM)
and-ISDN) exchange technology was agreed by CCITT,
Further, it is being prescribed to separate a signal for call processing (call control signal) from a signal for connection processing (connection control signal).

[0002]

2. Description of the Related Art In order to perform a call control process and a connection control process separately, a call control unit and a connection control unit are provided for each, and a call process is performed while signals are exchanged between the control units according to a prescribed sequence. Need to do. For example, when the call control signal is received, the call control unit is activated, then when the connection control signal is received, the connection control unit is activated, and when the connection control unit is activated, a predetermined signal is sent to the call control unit according to a specified sequence. However, after that, each control unit needs to perform signal processing according to the specified sequence to perform call processing. By the way, it is expected that the transmission order (or arrival order) of the call control signal and the connection control signal will be the reverse of the prescribed sequence in the ATM switch due to its super-multiplicity and the occurrence of interrupts due to fault processing activation. That is, it is expected that what should arrive in the order of call control signal → connection control signal will arrive in the reverse order. In this case, the connection control unit is activated before the call control unit is activated, and the connection control unit sends out a signal specified by the call control unit. However, since the call control unit is not activated, the signal disappears and the multi-connection connection service cannot be performed.

[0003]

From the above, it is necessary to take measures when the signal sequence is different from the prescribed sequence. However, in the conventional STM network, the types of media that can be communicated are limited because the types of lines that can be handled are limited, and the signals are not separated into calls and connections. It was not necessary to consider measures when the sequence was different from the specified sequence. From the above,
An object of the present invention is to provide an ATM exchange capable of performing correct call processing without loss of signals even when the arrival sequence of call control signals and connection control signals is different from the prescribed sequence.
It is to provide a signal synchronization control system in an exchange and an ATM exchange.

[0004]

FIG. 1 is a diagram for explaining the principle of the present invention. Reference numeral 21 is a signal processing unit for receiving a signal from a subscriber or another exchange, 31 is a control unit activation unit, 31a is a signal buffer provided in the control unit activation unit, and 32a is activated in response to a call by a call control signal. A call control unit that controls the entire call, 33a is a connection control unit that is activated by a connection control signal and controls the establishment and release of a connection path, and 34a is provided in the connection control unit and is a monitoring function that monitors the activation of the call control unit. It is a department.

[0005]

[Operation] Connection control signal B-SE is sent to the control unit starting unit 31.
A signal buffer 31a (see FIG. 1A) for storing TUP is provided. The control unit activation unit 31 includes a call control signal C-SETUP and a connection control signal BS in the order specified by the signal processing unit 21.
When receiving ETUP, the call control unit 32a is activated by receiving the call control signal C-SETUP, the call control signal is passed, and then,
Upon receiving the connection control signal B-SETUP, the connection control unit 33a is activated to start the connection control signal B-SETU.
When P is passed, the connection control unit 33a, when activated, sends a predetermined signal to the call control unit 32a in accordance with a prescribed sequence, and thereafter each control unit performs signal transmission / reception in accordance with the prescribed sequence to perform call processing. On the other hand, the control unit starting unit 31
When receiving the connection control signal B-SETUP before receiving the call control signal C-SETUP, the connection control signal is stored in the signal buffer 31a, and thereafter, the call control signal C-SETUP is received.
When the SETUP is received, the call control unit 32a is activated, and then the connection control unit 33a is activated to pass the connection control signal B-SETUP stored in the signal buffer 31a to the connection control unit, and the sequence specified thereafter. Perform processing according to. Even if the control signals are received in an order different from the order specified in this way, the connection control unit is not activated until the call control signal is received and the call control unit is activated. Even if the signal arrival order is out of order, the signal does not disappear, and the multi-connection connection service can be provided.

Further, the connection control unit 33a is provided with a monitoring function unit 34a (see FIG. 1B) for monitoring activation of the call control unit 32a, and when the connection control unit 33a is activated, the call control unit 33a is activated. After confirming that 32a is activated, a predetermined signal is transmitted in accordance with a prescribed sequence to the call control unit 3.
2a, and thereafter each control unit performs signal processing by exchanging signals in accordance with the specified sequence. In this way, even if the order of arrival of signals is deviated, signal exchange is started after the call control unit is activated, so that no signal disappears and a multi-connection connection service can be provided.

[0007]

【Example】

(A) Outline of ATM network In the ATM system, multiple logical links are provided on a physical line to allocate the line to a plurality of calls. Then, moving image data, voice data, and the like from the terminal corresponding to each call are decomposed into fixed-length information units (called cells) and sequentially sent to the line to realize multiplexing. The cell is 53 as shown in FIG.
It is composed of a fixed length block of bytes, of which 5 bytes are a header part HD and 48 bytes are an information field (information part) DT. The header part HD has a virtual channel number (Virtual Channel Identifie) for call identification so that the destination can be known even after the data is decomposed into blocks.
r: VCI) is included, and a virtual path identifier (VPI) that specifies a route is also included,
A generic flow control GFC (Generic Flow Control) used for flow control between links, a payload PT (Payload Type), a header error correction code HEC (Header Error Control), and the like are included.

FIG. 3 is an ATM for explaining the ATM system.
It is a schematic block diagram of a network, 11a and 11b are terminal devices, 1
3 is an ATM network. The ATM network 13 includes an information network 13a for transmitting data cells and a signal network 13b for transmitting control signals.
And each ATM switch 13c-1 in the information network 13a.
CPUs 13d-1 to 4d-n of 13c to 13c-n are connected to the signal network 13b. When the calling terminal 11a performs a calling operation for calling the called terminal 11b, the cell assembling unit in the calling terminal divides the data including the calling number, the called number, the type of the terminal, the attribute, etc. into cell units and divides each of the divided cells. The signal VCI (predetermined for each terminal) is attached to the data to generate a signal cell,
The signal cell is sent to the ATM network 13.

When the signaling device (not shown) of the ATM exchange (transmission side exchange) 13c-1 receives a signal cell, it assembles the information contained in the signal cell and notifies the CPU 13d-1. The CPU performs call processing such as caller service analysis processing, billing processing, callee digit translation processing, and the like.
I) and call identification information (VCI) are determined, and the signaling network 13b
Via NO. According to the No. 7 protocol, connection information including a calling number, a called number, VPI, VCI and other data is sent to the next transit exchange. After that, the transit exchange performs the same process, and finally the ATM exchange (incoming exchange) 13c- to which the incoming terminal is connected from the outgoing exchange 13c-1.
Paths up to n and relay ATM switches 13c-2, 13c-3, ...
Is determined. Upon receiving the connection information including the calling number, the called number, and the VCI of the upper ATM switch, the called exchange 13c-n assigns a predetermined VCI to the called terminal and checks whether the called terminal 11b can talk. If the call is possible, the signaling network 13b indicates that the call can be made.
c-1 is notified and the originating exchange allocates a predetermined VCI to the originating terminal 11a.

Each ATM switch 13c-1 to 13c-n on the path
Corresponds to the VCI of the upper ATM switch for each path,
(1) Output path (output highway) of the cell having the VCI
And (2) register new VCI and VPI to be added to the output cell in the built-in routing table. From the above, the sending terminal 11a and the receiving terminal 1
When a path is formed between 1b, both terminals send and receive a calling cell and a responding cell to confirm the communication procedure. Thereafter, the transmitting terminal 11a decomposes the data to be transmitted into a predetermined byte length, attaches a header containing the assigned VCI to generate a cell, and sends the cell to the ATM network 13. When each ATM switch 13c-1 to 13c-n receives a cell from a host switch via a predetermined input highway,
VC of the input cell based on the routing table
Change I and send it to the designated exit highway.
As a result, the cell output from the calling terminal 11a reaches the terminating side exchange 13c-n via the path determined by the call control. Based on the routing table, the terminating exchange 13c-n replaces the VCI added to the input cell with the VCI assigned to the terminating terminal, and then the terminating terminal 11b.
To the line to which is connected.

Thereafter, the calling terminal 11a sequentially sends cells to the called terminal 11b, and the called terminal assembles the information part DT included in the received cell to restore the original data. The above is 1
For one call, by changing the VCI values held at both ends of each line between the terminal-ATM switch and the adjacent ATM switch, it is possible to set up a logical link corresponding to many calls on one line. Therefore, high-speed multiplex communication can be realized. According to the ATM method, since information of information sources having different transmission speeds such as moving images, data, and voice can be multiplexed, one transmission line can be effectively used, and packet exchange can be performed by software. There is no need for retransmission control and complicated communication procedures as described above, and ultra-high-speed data transmission of 150 Mbps is possible.

(B) Overall operation when call control processing and connection control processing are separated FIG. 4 shows a case where call control processing and connection control processing are separated A
It is operation | movement explanatory drawing of a TM exchange. In the figure, reference numerals 1 and 2 denote multimedia terminals, such as videophones, and 10, 50.
Is an ATM switch. No ATM switch is shown in each of the ATM exchanges 10 and 50, and only the CPU is shown.
In the ATM switch 10, 20 is an OS (operating system) and 30 is a basic call processing unit (application unit). In the operating system 20, 21 is a base for receiving signals from the multimedia terminal 1.
The signal processing unit (DSS) 22 for converting into a data structure that can be easily processed by the call processing unit 30 is activated by a system call from the basic call processing unit 30, and is routed to a route (VPI) designated according to the call admission control algorithm. A communication path control unit (SW) that determines whether there is a vacancy in the specified band and notifies it
C) and 23 are signal processing units (ISUP) for exchanging signals with other exchanges.

In the basic call processing unit 30, 31 is a task activation unit (control unit activation unit), 32a is a call control task (call control unit), 33a ₁ is a voice connection control task (voice connection control unit), and 33a ₂ is This is a video connection control task (video connection control unit). One task activation unit 31 is provided in the exchange, and the call control signal C-SETUP is provided.
Is accepted and the call control task 32a corresponding to the call is activated and the B-SE
Upon receiving the TUP, the connection control tasks 33a ₁ and 33a ₂ corresponding to the connection are activated. Call control task 32a
Is started by the task starting unit 31, and the signal processing unit 21,
Signals are exchanged with the control unit 23 to control the entire call such as charging control and the same route selection control for each connection. The connection control tasks 33a ₁ and 33a ₂ are activated by the task activation unit 31 for each connection, and perform reservation, acquisition and release processing of a path (VCI) in a route (VPI) designated by the call control task 32a. .

In the ATM switch 50, 60 is an OS
(Operating system), 70 is a basic call processing unit
( Application section). In the operating system 60, 61 is a signal processing unit (DSS) that receives a signal from the multimedia terminal 2, 62 is a communication path control unit (SWC), and 63 is a signal processing unit (ISUP) that exchanges signals with other exchanges. Is. In the application section 70, 71 is a task starting section (control section starting section), 7
2a is a call control task (call control unit), 73a ₁ is a voice connection control task (voice connection control unit), 73a ₂
Is a video connection control task (video connection control unit).

In the case of making a videophone call from the media terminal 1 accommodated in the ATM exchange 10 to the multimedia terminal 2 accommodated in another exchange 50, in other words, each connection of voice and video is set at the time of call setup. The case of simultaneous connection will be described. 5, 6 and 7 are sequence flow diagrams for realizing the videophone service.

(A) When the key for the videophone is pressed from the multimedia terminal 1 to input the telephone number of the other party, the terminal 1 sends out a call control signal C-SETUP (including the outgoing and incoming numbers) and A connection control signal B-SETUP (including a band (transmission speed), a peak value, a burst property, etc.) is sent to the exchange 10 for each voice connection and moving picture connection. The signal processing unit 21 of the exchange 10 uses the call control signal C-SETUP.
→ Task control block 3 in the order of connection control signal B-SETUP
Send to 1. (b) The task activation unit 31 activates the call control task 32a for the terminal 1 based on the call control signal C-SETUP sent from the signal processing unit, passes the call control signal, and then,
Audio and video connection control signals B-SETU
Connection control tasks 33a _{1 to} 33a ₂ based on P
And the connection control signal is passed to each.

(C) Each connection control task 33a _1-
33a ₂ displays the band information included in the received B-SETUP signal.
The call control task 32a is notified by the B-REQ signal. The call control task 32a includes connection control tasks 33a _1-
If the band notification is received from 33a ₂ , a plurality of routes (VPI) to the receiving terminal are obtained, and one of the VPIs is B-
Each connection control task 33a _{1 to} 33 by SEL signal
Specify to a ₂ . Each connection control task 33a ₁ ~3
3a ₂ checks whether or not there is a margin for transmitting voice and moving image in the designated VPI band, and if there is a margin, reserves a predetermined VCI for the VPI and voice and moving image connection, and The B-RES signal is used to notify the call control task 32a. As described above, the same route (VPI) and VCI for each connection are reserved for each connection of voice and moving image.

(D) When the reservation of the same VPI is completed, the call control task 32a receives the reserved V via the signal processing unit 23.
The C + B-SETUP signal is sent to the ATM exchange (the exchange 50 that accommodates the terminal 2 in FIG. 4) to which the PI is connected. Switch 5
The signal processing unit 63 of 0 sends these signals to the task starting unit 71 because these signals are call setting and connection setting signals. (e) Based on the signal sent from the signal processing unit, the task starting unit 71 uses the call control task 72a for the terminal 2 and the connection control tasks 73a ₁ to ₁
73a ₂ is generated, and the C-SETUP signal and the B-SETUP signal are passed to each of them to activate them.

(F) Each connection control task 73a _1-
73a ₂ sets the band information contained in the received B-SETUP signal to B-
The call control task 72a is notified by the REQ signal. Call control task 72a each connection control task 73a ₁ ~73a ₂
If the band notification is received from the
Seeking I), it is assigned to each connection control task 73a ₁ ~73a ₂ the VPI by B-SEL signal. If there is a margin for transmitting the voice and the moving image in the band of the specified VPI, a predetermined VCI is reserved for the VPI and the voice and the moving image connection, and the reservation completion is made by the call control task by the B-RES signal. Notify 72a. As described above, the same route (VPI) is reserved for each connection of voice and moving image. (g) When the reservation is completed, the call control task 72a sends a C-SETUP signal to the terminal 2 via the signal processing unit 61.

(H) Also, the call control task 72a is
Video connection control task 73a ₁~ 73a₂To all connections
B-SUC signal that the reservation of the action was successful
The notified connection control task is the signal processing unit 6
A B-SETUP signal is sent to the terminal 2 via 1. (i) Terminal 2 responds by receiving C-SETUP and B-SETUP signals
If possible, the signal processing unit 6 sends an ALT signal indicating that response is possible.
1 to the call control task 72a. Call control task
72a is a call control task via the signal processing units 63 and 23.
The ALT signal is sent to 32a. This allows the call control task
32a receives the ALT signal from the terminal 1 via the signal processing unit 21.
Send to.

(J) After the ALT signal is transmitted, the terminal 2 sends the C-CONN and B-CONN signals to the signal processing unit 61 when the called party goes off-hook.
To the call control task 72a and the connection control tasks 73a ₁ and 73a ₂ respectively. Each of the connection control tasks 73a ₁ and 73a ₂ is assigned to the VP reserved in advance.
After capturing I and VCI and setting up a connection, a B-EST signal is sent to the call control task 72a. (k) As a result, the call control task 72a sends the C + B-CONN signal to the call control task 32a via the signal processing units 63 and 23. (m) The call control task 32a sends the C-CONN signal to the signal processing unit 21.
Then, the B-CONN signal is sent to each of the connection control tasks 33a ₁ and 33a ₂ after being sent to the terminal 1 via the.

(N) Each connection control task 33a ₁ ,
33a ₂ captures the previously reserved VPI and VCI,
After setting the connection, the B-CONN signal is transmitted to the terminal 1 via the signal processing unit 21. As described above, a multi-connection for voice and moving images is established between the terminal 1 and the terminal 2, and the videophone is in communication. (o) When communication is completed and the terminal 1 is disconnected, the terminal 1
The C-REL and B-REL signals are transmitted via the signal processing unit 21 to the call control task 32a and the connection control task 33a, respectively.
₁ to 33a ₂ .

(P) Each connection control task 33a ₁ ,
After releasing the VPI and VCI being captured, 33a ₂ sends a B-DEL signal to the call control task 32a and terminates its own task. (q) Upon receiving the B-DEL signal, the call control task 32a becomes C + B
-Send the REL signal to the call control task 72a via the signal processing units 23 and 63. (r) The call control task 72a sends a C-REL signal to the terminal 2 via the signal processing unit 61, and then sends a B-REL signal to each of the connection control tasks 73a ₁ and 73a ₂ .

(S) Each connection control task 73a ₁ ,
73a ₂ sends a B-DEL signal to the call control task 72a after releasing the VPI and VCI being captured, and then sends a B-REL signal to the terminal 2 via the signal processing unit 61. End the task. (t) As a result, the terminal 2 sends out the C-RELCOM signal. (u) The call control task 72a sends a C-RLC signal to the call control task 32a via the signal processing units 63 and 23, and then terminates its own task, and the call control task 32a receives the C-RLC signal. Terminates the invoking task.

As described above, in the ATM switch,
The signal processing unit 21 calls these signals in the order of the call control signal and the connection control signal, and these signals are the task activation unit (control unit activation unit).
Then, the task activation unit 31 activates the call control task (call control unit) 32a and the connection control tasks (connection control units) 33a ₁ and 33a ₂ in this order. When the connection control tasks 33a ₁ and 33a ₂ are activated, they send a B-REQ signal to the call control task 32a .
Call processing is performed according to the sequence shown in 7 while exchanging control signals.

By the way, due to the super-multiplicity of the ATM switch and the occurrence of an interrupt due to the activation of a failure process, the signal processing unit 21
If the transmission order of the call control signal and the connection control signal transmitted from the device is reversed, the connection control tasks 33a ₁ and 33a ₂ are activated before the call control task 32a is activated, and the connection control task switches from the call control task to the call control task. B-RE
Q signal is sent. However, at this time, call control task 3
Since 2a has not started yet, the B-REQ signal cannot be received, the B-REQ signal disappears, and the multi-connection connection service cannot be performed. Therefore, it is necessary to take measures when the signal sequence is different from the prescribed sequence.

(C) Overall configuration of the first embodiment of the present invention FIG. 8 and FIG. 9 are explanatory diagrams of the configuration and operation of an ATM switch which takes measures when the signal order is different. In addition, ATM
The switches are not shown, only the CPU is shown. 20
Is an OS (operating system), 21 is a signal processing unit that receives a signal from a subscriber or another exchange, 30 is a basic call processing unit (application unit), 40 is a shared memory, 41 is a real process ID and a logical process ID It is a table that manages the correspondence of.

In the basic call processing unit 30, 31 is a control unit activation unit, 31a is a signal buffer for storing connection control signals provided in the control unit activation unit, 31b is a logical process ID management unit, and 32a is the entire call control. Call control unit,
A connection control unit 33a controls establishment and release of a connection path. The control unit activation unit 31 activates the call control unit 32a when receiving the call control signal C-SETUP, and activates the connection control unit 33a when receiving the connection control signal B-SETUP. The call control unit 32a is activated by the control activation unit 31 and controls the entire call such as charging control and the same route selection control for each connection based on the information included in the call control signal C-SETUP. Each connection control unit 33
a is activated for each connection by the control unit activation unit 31, and is a route (VPI) designated by the call control control unit 32a.
Reservation, acquisition and release processing of the internal path (VCI). Although only one connection control unit 33a is shown for the sake of explanation, two or more connection control units 33a may be provided.

Overall operation (a) Normal operation (see FIG. 8) Call control signal C-SETUP (transmission,
Connection control signal B-SETU together with the called number)
When P is sent, the signal processing unit 21 of the ATM switch
Sends a call control signal C-SETUP to the control unit activation unit 31. Upon receiving the call control signal C-SETUP, the control unit activation unit 31 requests the operating system 20 to activate the call control unit 32a. In response to the activation request, the operating system 20 activates the call control unit 32a (actually generates a call control task), and the real process ID (11
1) is notified to the control unit starting unit 31. When the control unit starting unit 31 receives the real process ID (111), the logical process ID management unit 31b receives the call ID (C1).
And the logical process ID (callee) of the call control unit.
Then, the real process ID (111) is registered in the table 41 of the shared memory 40 in association with the call ID and the logical process ID (C1.callee).

Thereafter, the control unit activation unit 31 passes the call control signal C-SETUP and the logical process ID (C1.callee) of the call control unit to the call control unit 32a. After that, the signal processing unit 21 determines that the connection control signal
B-SETUP is sent to the control unit activation unit 31. Upon receiving the connection control signal B-SETUP, the control unit activation unit 31 determines whether the call control signal C-SETUP has already been received. If the call control signal C-SETUP is received, the connection control unit 33a is sent to the operating system 20.
Request to start. In response to the activation request, the operating system 20 activates the connection control unit 33a (actually creates a connection control task) and notifies the control unit activation unit 31 of the actual process ID (222) of the connection control unit. To do.

The control unit start-up unit 31 uses the real process ID (22
2) is received, the logical process ID management unit 31b causes the logical process ID (calle
r) is determined. Then, call the real process ID (222) I
D is registered in the table 41 of the shared memory 40 in association with the logical process ID (C1.caller). When there are two or more connections (for example, audio and video connections), the connection control unit is activated for each, and the logical process ID and the real process ID are determined and registered in the table 41. Thereafter, the control unit activation unit 31 passes the connection control signal B-SETUP and the logical process ID (C1.caller) of the connection control unit to the connection control unit 33a. Connection control unit 33
a uses the logical process ID ( C1.callee ) as a keyword to obtain the real process ID (111) of the call control unit 32a from the table 41 of the shared memory. Similarly, the call control unit 32a uses the logical process ID ( C1.caller ) as a keyword from the table 41 to determine the actual process I of the connection control unit 33a.
Find D (222).

Then, the connection controller 33a
Adds the real process ID (111) of the call control unit to the band information included in the received B-SETUP signal and notifies the call control unit 32a (interprocess communication). Thereafter, each control unit adds the other party's real process ID in accordance with the sequence of FIGS. The above is a case where the signal processing unit 21 inputs the call control signal C-SETUP → connection control signal B-SETUP to the control unit activation unit 31 in the specified order. It may be input to the section 31. At the time of such an abnormality, it operates as follows.

(B) At the time of abnormality (see FIG. 9) The signal processing unit 21 of the ATM exchange mistakenly first makes a connection control signal B- by a call from the multimedia terminal.
SETUP is sent to the control unit activation unit 31. Control unit starting unit 3
1 receives the connection control signal B-SETUP, checks whether the call control signal is already received, and if not, stores the connection control signal B-SETUP in the signal buffer 31a, Wait to receive. In this state, the signal processing unit 21 outputs the call control signal C-SETUP.
To receive. Upon receiving the call control signal C-SETUP, the control unit activation unit 31 requests the operating system 20 to activate the call control unit 32a. In response to the activation request, the operating system 20 activates the call control unit 32a (actually generates a call control task), and the real process ID (11
1) is notified to the control unit starting unit 31.

The control unit starting unit 31 determines the real process ID (11
When 1) is received, the logical process ID management unit 31b causes the call ID (C1) and the logical process ID (callee) of the call control unit.
To decide. Next, call the real process ID (111) as the call ID,
It is registered in the table 41 of the shared memory 40 in association with the logical process ID (C1.callee). Thereafter, the control unit activation unit 31 informs the call control unit 32a of the call control signal C-SETUP and the logical process ID (C1.calle) of the call control unit.
pass e). When the above process is completed, the control unit activation unit 31 requests the operating system 20 to activate the connection control unit 33a. In response to the activation request, the operating system 20 activates the connection control unit 33a (actually creates a connection control task) and notifies the control unit activation unit 31 of the actual process ID (222) of the connection control unit. To do.

The control unit start-up unit 31 uses the real process ID (22
When 2) is received, the logical process ID management unit 31b causes the logical process ID (caller) of the connection control unit to be received.
To decide. Then, the real process ID (222) is the call ID,
It is registered in the table 41 of the shared memory 40 in association with the logical process ID (C1.caller). After that, the control unit activation unit 31 informs the connection control unit 33a of the connection control signal B-SETUP and the logical process I of the connection control unit.
Pass D (C1.caller). The connection control unit 33a obtains the real process ID (111) of the call control unit 32a from the table 41 of the shared memory using the logical process ID ( C1.callee ) as a keyword. Similarly, the call control unit 32a uses the logical process ID ( C1.caller ) as a keyword to retrieve the actual process ID of the connection control unit 33a from the table 41.
Find (222).

Then, the connection control unit33a
Controls the call based on the band information included in the received B-SETUP signal.
Part real process ID (111) is added to the call controller 32a.
Notice. After that, each control unit follows the sequence of Fig. 5 to Fig. 7.
Send and receive signals by adding the actual process ID of the other party
Call processing. As described above, the control unit starting unit 31
Even if the connection control signal is received before the call control signal,
The connection control block is activated until the call control signal is received.
This prevents the signal from disappearing even if the signal arrival order is out of order.
Without loss, multi-connection connection service
It

(D) Second Embodiment of the Present Invention FIG. 10 and FIG. 11 are diagrams for explaining the configuration and operation of the second embodiment of the present invention in which measures are taken when the signal order is different.
The ATM switch is not shown, but only the CPU is shown. The same parts as those of the first embodiment shown in FIGS. 8 and 9 are designated by the same reference numerals. The difference from the first embodiment is that
The signal buffer is deleted from the control unit starting unit 31, and the connection control unit 33a is provided with a monitoring function unit 34a for monitoring the activation of the call control unit.

Overall Operation (a) Normal state (see FIG. 10) Call control signal C-SETUP (calling, sending from multimedia terminal)
Connection control signal B-SETU together with the called number)
When P is sent, the signal processing unit 21 of the ATM switch
First sends a call control signal C-SETUP to the control unit activation unit 31. Upon receiving the call control signal C-SETUP, the control unit activation unit 31 requests the operating system 20 to activate the call control unit 32a. In response to the activation request, the operating system 20 activates the call control unit 32a (actually generates a call control task), and the real process ID (11
1) is notified to the control unit starting unit 31. When the control unit activation unit 31 receives the real process ID (111), the control unit activation unit 31b causes the call ID (C
1) and the logical process ID (callee) of the call control unit 32a are determined. Then, the real process ID (111) is associated with the call ID and the logical process ID (C1.callee), and the shared memory 40
Registered in the table 41 of FIG.

When the above processing is completed, the control unit starting unit 3
1 passes the call control signal C-SETUP and the logical process ID (C1.callee) of the call control unit to the call control unit 32a. After that, the signal processing unit 21 determines that the connection control signal
B-SETUP is sent to the control unit activation unit 31. Upon receiving the connection control signal B-SETUP, the control unit activation unit 31 requests the operating system 20 to activate the connection control unit 33a. In response to the activation request, the operating system 20 activates the connection control unit 33a (actually generates a connection control task), and the actual process ID (222) of the connection control unit is generated.
The control unit starting unit 31 is notified.

The control unit starting unit 31 determines the real process ID (22
When 2) is received, the logical process ID management unit 31b determines the logical process ID (caller) of the connection control unit 33a. Next, call the real process ID (222) as the call ID,
It is registered in the table 41 of the shared memory 40 in association with the logical process ID (C1.caller). The connection is 2
In the above cases (for example, audio and video connection), the connection control unit is activated for each, and the logical process ID and the real process ID are determined and registered in the table 41. After that, the control unit activation unit 31 determines that the connection control unit 3
The connection control signal B-SETUP and the logical process ID (C1.caller) of the connection control unit are passed to 3a.

The call control unit activation monitoring function unit 34a of the connection control unit 33a uses the call ID (C1) corresponding to itself as a keyword in the shared memory table 41 in the call control unit 32a.
Whether the real process ID of a is registered, in other words,
It is checked whether the call control unit 32a is activated (monitoring). 'If the call control unit 32a has been activated, the connection control unit 33a uses the logical process ID ( C1.callee ) as a keyword to retrieve the call control unit 32 from the shared memory table 41.
The actual process ID (111) of a is obtained. Similarly, the call control unit 32a obtains the actual process ID (222) of the connection control unit 33a from the table 41 using the logical process ID ( C1.caller ) as a keyword.

Then, the connection control unit33a
Controls the call based on the band information included in the received B-SETUP signal.
Part real process ID (111) is added to the call controller 32a.
Notice. After that, each control unit follows the sequence of Fig. 5 to Fig. 7.
Send and receive signals by adding the actual process ID of the other party
Call processing. Above, the signal processing unit 21 is defined.
Call control signal C-SETUP → connection control signal B
-When SETUP is input to the control unit activation unit 31,
The order may be reversed and the data may be input to the control unit activation unit 31.
It At the time of such an abnormality, it operates as follows.

(B) In the case of an abnormality (see FIG. 11) The signal processing unit 21 of the ATM exchange mistakenly first makes a connection control signal B- by a call from the multimedia terminal.
SETUP is sent to the control unit activation unit 31. Upon receiving the connection control signal B-SETUP, the control unit activation unit 31 requests the operating system 20 to activate the connection control unit 33a. In response to the activation request, the operating system 20 activates the connection control unit 33a (actually generates a connection control task), and the actual process ID (222) of the connection control unit is generated.
The control unit starting unit 31 is notified. When the control unit activation unit 31 receives the real process ID (222), the logical process ID management unit 31b causes the call ID and the logical process ID (caller) of the connection control unit 33a.
To decide. Then, the real process ID (222) is the call ID,
It is registered in the table 41 of the shared memory 40 in association with the logical process ID (C1.caller).

Thereafter, the control unit starting unit 31 passes the connection control signal C-SETUP and the logical process ID (C1.caller) of the connection control unit to the connection control unit 33a. The call control unit activation monitoring function unit 34a of the connection control unit 33a checks whether the real process ID of the call control unit 32a is registered in the table 41 of the shared memory using the call ID (C1) corresponding to itself as a keyword (monitoring). . If the real process ID is not registered, the call control unit 32a is not activated, and thereafter the activation of the call control unit 32a is continuously monitored. In this state, the control unit activation unit 31 receives the call control signal C-SETUP from the signal processing unit 21.

The control unit starting unit 31 uses the call control signal C-SETUP.
If it receives, the operating system 20 is requested to activate the call control unit 32a. In response to the activation request, the operating system 20 activates the call control unit 32a (actually creates a call control task) and notifies the control unit activation unit 31 of the real process ID (111) of the call control unit. To do. When the control unit activation unit 31 receives the real process ID (111), the logical process ID management unit 31b causes the call control unit 32 to operate.
The logical process ID (callee) of a is determined. Then,
The real process ID (111) is the call ID and the logical process ID (C1.c
Allee) is registered in the table 41 of the shared memory 40. Thereafter, the control unit activation unit 31 informs the call control unit 32a of the call control signal C-SETUP and the logical process ID (C1.calle) of the call control unit.
pass e).

As described above, the call control unit activation monitoring function unit 34a recognizes the activation of the call control unit 32a.
After that, the connection control unit 33a sends the logical process ID ( C
Table 4 of shared memory with 1.callee ) as a keyword
The actual process ID (111) of the call control unit 32a is obtained from 1. Similarly, the call control unit 32a receives the logical process ID ( C1.
(caller ) as a keyword, the actual process ID (222) of the connection control unit 33a is obtained from the table 41. 'Next, the connection control unit 33a receives the received B-
The real process ID (111) of the call control unit is added to the band information included in the SETUP signal and the call control unit 32a is notified. Thereafter, each control unit adds the real process ID of the other party in accordance with the sequence of FIGS.

With the above arrangement, even if the signal arrival order is shifted, the signal is not lost since the signal transfer is started after the call control unit is activated, and the multi-connection connection service can be provided. Although the present invention has been described above with reference to the embodiments, the present invention can be variously modified according to the gist of the present invention described in the claims, and the present invention does not exclude these.

[0048]

As described above, according to the present invention, even if the control signals are received in the order different from the prescribed order, the connection control unit is not activated until the call control signal that should arrive first is received. Therefore, even if the signal arrival order is shifted, the signal does not disappear and the multi-connection connection service can be provided. Further, according to the present invention, the connection control unit is provided with a monitoring function unit for monitoring activation of the call control unit, and when the connection control unit is activated, it is confirmed that the call control unit is activated. Since the predetermined signal is transmitted to the call control unit according to the prescribed sequence after that, even if the signal arrival order is shifted, the signal does not disappear and the multi-connection connection service can be provided.

[Brief description of drawings]

FIG. 1 is a diagram illustrating the principle of the present invention.

FIG. 2 is a block diagram of an ATM cell.

FIG. 3 is a schematic explanatory diagram of an ATM network.

FIG. 4 is a diagram for explaining the operation of the ATM exchange.

FIG. 5 is a sequence flow diagram (part 1) for realizing a videophone service.

FIG. 6 is a sequence flow diagram (part 2) for realizing a videophone service.

FIG. 7 is a sequence flow diagram (part 3) for realizing a videophone service.

FIG. 8 is a diagram illustrating the configuration and operation of the first embodiment of the present invention (when normal).

FIG. 9 is a diagram illustrating the configuration and operation of the first embodiment of the present invention (when an abnormality occurs).

FIG. 10 is a diagram illustrating a configuration and an operation (normal) of the second embodiment of the present invention.

FIG. 11 is a diagram illustrating the configuration and operation of the second embodiment of the present invention (when an abnormality occurs).

[Explanation of symbols]

21 .. Signal processing unit 31 .. Control unit starting unit 31a ... Signal buffer 32a ... Call control unit 33a ... Connection control unit 34a ... Call control unit start-up monitoring function unit

Continuation of the front page (56) Reference JP-A-6-169318 (JP, A) JP-A-5-327754 (JP, A) JP-A-5-268254 (JP, A) JP-A-5-268252 (JP , A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H04L 12/56

Claims (4)

(57) [Claims] 1. A call control unit (32a) for controlling the entire call in a signal synchronization control system in an ATM switch for controlling a plurality of connections by a single call from a terminal connected to an ATM switch in an asynchronous transfer mode, Connection control unit (33a) that controls the establishment and release of paths for each connection
And receiving the call control signal to activate the call control unit,
The control unit starting unit (31) that receives the connection control signal and starts the connection control unit is provided, and the control unit starting unit is provided with the signal buffer (31a) that stores the connection control signal. When receiving the call control signal and the connection control signal in this order, the call control unit is activated by receiving the call control signal and the call control signal is passed, and then the connection control unit is activated by receiving the connection control signal and the connection is established. When the control signal is passed and the connection control unit is activated, it sends a predetermined signal to the call control unit in accordance with a prescribed sequence, and thereafter each control unit performs signal processing by exchanging signals in accordance with the prescribed sequence and performs call processing. Stores the connection control signal in the signal buffer if it receives the connection control signal before receiving the call control signal. After that, when the call control signal is received, the call control unit is activated, and then the connection control unit is activated to pass the connection control signal stored in the buffer to the connection control unit, and thereafter, the processing is performed according to the specified sequence. A signal synchronization control system in an ATM exchange characterized by being executed. 2. A call control unit (32a) for controlling the entire call in a signal synchronization control system in an ATM switch for controlling a plurality of connections with a single call from a multimedia terminal connected to an ATM switch in an asynchronous transfer mode. And a connection control unit (33a) that controls the establishment and release of paths for each connection.
And receiving the call control signal to activate the call control unit,
A control unit starting unit (31) for receiving a connection control signal and activating the connection control unit is provided, and the connection control unit is provided with a monitoring unit (34a) for monitoring that the call control unit has been started up. When activated, it confirms that the call control unit is activated and then sends a predetermined signal to the call control unit according to a specified sequence. Thereafter, each control unit performs signal transfer according to the specified sequence to perform call processing. A signal synchronization control system in an ATM exchange characterized by performing the following. 3. The control unit starting unit (31), upon receiving the call control signal and the connection control signal, determines a logical process ID for identifying the call control unit and the connection control unit, notifies them to the respective control units, and separately determines them. The correspondence between the real process ID of each control unit and the logical process ID is stored in the memory, and each control unit accesses the memory using the logical process ID to identify the real process ID of the partner control unit. I
When D is added to the signal and the signal is transmitted / received to / from the partner control unit, the monitoring unit of the connection control unit monitors whether the real process ID of the call control unit is stored in the memory,
3. The signal synchronization control system in an ATM exchange according to claim 2, wherein the activation of the call control unit is confirmed. 4. An ATM exchange for controlling a plurality of connections
In the exchange, A call control unit (32a) for controlling the entire call, A connection that controls the establishment and release of paths for each connection.
Control unit (33a), Receives the call control signal, activates the call control unit, and
Control that receives the control signal and activates the connection control unit
Part starting part (31), A signal for storing a connection control signal in the control unit starting unit.
No. buffer (31a) is provided, The control activation unit is connected before receiving the call control signal.
Connection control signal when receiving connection control signal
When a signal is stored in the signal buffer and a call control signal is received
Start the connection control unit and store it in the buffer
Pass a connection control signal to the connection control unit
ATM switch characterized by