JPH0121652B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a speed matching method for matching communication speeds between terminals, network, and terminals in a communication system in which terminal devices whose communication speeds can be switched communicate via a switching network. Regarding communication methods.

Conventionally, as shown in FIG. 1, as a method for selecting a communication speed and communicating between a terminal, a network, and a terminal, a calling terminal 1 sends a speed switching request signal 5 to an exchange 2 before communication. The exchange 2 receives the channel assignment signal 6 from the exchange 2 or unilaterally notifies the desired communication speed in the calling signal 7, and the exchange 2 receives the incoming call signal 8.
This speed is notified to the destination terminal 4, and if the destination terminal 4 is able to communicate at this speed, it sends a response signal 9 to the exchange 2.
After setting up an intra-network path at the designated communication speed, the exchange 2 returns a connection completion signal 10 to the originating terminal 1, and then a communication signal 11 is sent and received between the two terminals. After the communication is completed, in response to the disconnection request signal 12 from the originating terminal 1, the exchange 2 sends a disconnection instruction signal 13 to the destination terminal 4, the destination terminal 4 returns a disconnection confirmation signal 14, and the exchange 2 releases the connection line. and sends a disconnection confirmation signal 15 to the originating terminal 1. In the conventional method described above, it is necessary for the originating terminal 1 to know the communication speed of the destination terminal 4 in advance, which is extremely inconvenient when many destination terminals have different communication speeds.

In recent years, digital service networks (Integrated Service Networks) that provide telephone services and non-telephone services (data communication services, etc.) in one network configuration have been introduced.
Discussions regarding the Servis Digital Network (ISDN) are being actively conducted in various countries. In ISDN, there are phones with various speeds that use PCM 64kb/s, 32 and 16kb/s phone signals due to band compression, and phones that can communicate at any of the above speeds. I think that the. Furthermore, even in the non-telephone field, it is expected that the demand for terminals that can communicate at multiple speeds such as 16 and 8 kb/s, such as digital facsimile, will increase. In such cases, the conventional method of unilaterally specifying the communication speed from the originating terminal to the network and destination terminal is as follows:
This is inconvenient because it requires the calling side to recognize the speeds of a large number of terminals. If the speed of the destination terminal is not recognized, it is extremely inconvenient because it is necessary to issue a speed change request signal several times and retry to match the speed.

In ISDN, as shown in Figure 2, subscriber line 2
3 one or more speech channels 17 and a call control channel 18 for transmitting control information.
are provided in a multiplex configuration. The communication channel 17 has a transmission capacity of, for example, 64 kb/s, and is capable of multiple communications at a speed below the maximum speed. For example, it can accommodate four communication paths with a communication speed of 16kb/s, one each of 32kb/s and 16kb/s, and two communication paths with 8kb/s. be. Such ISDN terminal 1
6, by using the conventional method described above, for example, 16kb/
There is an inconvenience in that when a request is made to communicate at 8 kb/s, even if the other party's terminal cannot use 16 kb/s but can use 8 kb/s. That is,
Conventional systems do not have flexibility in selecting communication speeds, and the probability that a call will be blocked (communication cannot be performed) even if there is an empty time slot (channel) depends on the channel usage status of multiple subscriber lines and the channel multiplexing configuration pattern. The disadvantage is that it is expensive.

For example, 9.6kb/s can be transmitted at 9.6kb/s depending on the calling terminal, like the fallback function of current telephone faxes.
It is possible to perform speed matching between terminals after setting up a path within the network so that the data can be transmitted. However, in this case, as shown in Figure 3a, if an intra-network path of 9.6 kb/s is set and communication between both terminals is performed at an effective speed of 4.8 kb/s,
This is uneconomical because a 9.6 kb/s transmission path is reserved for the effective communication speed of 4.8 kb/s.

The purpose of the present invention is to solve the above-mentioned conventional drawbacks and
The originating terminal can make a call without being aware of the communication speed of the destination terminal, and it is possible to match the communication speed between both terminals with a simple procedure. Therefore, provide an in-network pass,
Furthermore, it is an object of the present invention to provide an efficient and flexible speed matching communication system that can reduce the blocking rate on subscriber lines where multiple communication speeds can be used.

The communication system of the present invention includes a terminal device that can select from a plurality of communication speeds, and one or more exchanges that connect, disconnect, etc., and control the transmission path with the other terminal in response to a connection request from the terminal device. In the communication system, the switching network and one or more terminal devices are connected by a subscriber line consisting of a communication signal channel consisting of a plurality of time slots and a call control signal channel. , the originating terminal specifies one or more communication speeds and makes a call, and the switching network or the destination terminal is capable of realizing the communication speed specified by the originating terminal from among the communication speeds selectable by the destination terminal. If the number of free time slots exists in the communication signal channel of the subscriber line on the destination terminal side, the specified communication speed can be achieved, and if the number of free time slots that can achieve the communication speed specified by the originating terminal is If there is no communication signal channel on the subscriber line on the other side, the communication speed that can be achieved when all available time slots are used is notified to the originating terminal, and the communication speed between the originating and receiving terminals is determined based on the communication speed that can be achieved. Characterized by communicating.

Next, the present invention will be explained in detail with reference to the drawings.

FIG. 4 is a block diagram showing an example of the configuration of a digital communication system to which the speed matching communication method of the present invention is applied. That is, terminals 19, 21, 22
etc. are connected to the exchange 20 via subscriber lines 23, respectively. Although only one exchange 20 is shown in the figure, it may be a switching network including a plurality of exchanges and transmission lines connecting the exchanges.
Hereinafter, it is assumed that the exchange 20 includes such a switching network (network). The subscriber line 23 between the terminal 19 and the exchange 20 has a plurality of communication channels 25 of 64 kb/s,
It has a call control channel 26 capable of transmitting call control signals of 8 to 64 kb/s. Terminal 19 is 64kb/
This terminal is capable of simultaneous communication at multiple speeds of s or less.
The terminals 21 and 22 are terminals capable of communicating at a single speed or multiple speeds, and each has a communication speed of 16 kb/s,
It is connected to the exchange 20 by a subscriber line 23 having a speech channel with a communication speed of 8 kb/s and a call control channel with the required capacity. The call control channel is connected to a signal processing device 24 built into the exchange 20.

An example of the channel configuration of the subscriber line 23 is shown in FIG. That is, following the framing bit 35 indicating the beginning of the frame for synchronization, n(1
(an integer above) communication channels (hereinafter referred to as B channels) 36 and call control channels (hereinafter referred to as D channels) 37 are arranged, and one frame is transmitted at 125 microseconds. Since the B channel 36 is composed of 8 bits, the transmission speed is 64 kb/s. Each B channel uses 1 bit.Can be divided into 8 B' channels with a minimum speed of 8kb/s, each using 2 bits.
It is possible to divide into 4 16kb/s B'' channels and use 2 32kb/s B channels by using 4 bits each.It is also possible to combine the above various speeds. .If D channel 37 is 8 bits per frame, 64kb/
Call control signals can be transmitted at a speed of s.
The call control signal includes communication speed designation information and the like in addition to the called terminal number and the like.

Next, one embodiment of the present invention will be described. FIG. 6 is a diagram showing the sequence of the rate matching control procedure within the call setting procedure in this embodiment. That is, the calling signal 27 from the terminal 19 is a signal that sends call control information including the destination terminal number, communication speed designation information, etc. to the exchange (network) 20, and the exchange 20 that receives the signal, An incoming call signal 28 is sent to the incoming terminal 21 or 22. The incoming call signal 28 is a calling signal sent from the network to the incoming terminal, and includes communication speed designation information and the like. After receiving the incoming call signal 28, the destination terminal 21 or 22 returns a response signal 29. The response signal 29 includes usable communication speed information, channel information, etc. The exchange 20 receives the response signal 29, sets up necessary and sufficient intra-network paths, and sends a connection completion signal 30 to the originating terminal 19. The connection completion signal 30 includes information such as communication speed of the set path. If the originating terminal 19 cannot communicate at this communication speed, it sends a disconnection request signal 32 and the exchange 20 releases the connection. When the originating terminal 19 can communicate at the above-mentioned communication speed, it starts communicating with the destination terminal using the set communication path, and the communication signal 31 is exchanged between the originating and terminating terminals. After the communication ends, the originating terminal 19 sends a disconnection request signal 32, the exchange 20 sends a disconnection instruction signal 33 to the destination terminal, releases the path in response to a disconnection confirmation signal 34 from the destination terminal, and sends a disconnection confirmation signal 35 to the transmitting terminal 19. to finish everything. With such a control procedure, the following three types of speed designation methods can be realized.

(a) Single speed designation: The calling terminal 19 sends a calling signal 27 to the exchange 20 by specifying an arbitrary communication speed, for example, 16 kb/s, when making a call. The exchange 20 is
For example, by checking a file (not shown), etc., the time slot usage status of the call channel of the destination terminal 22 and the communication speed of the terminal 22 are known. For example, the communication speed (8 kb/s) (different from the specified communication speed) and the available time slot number are notified to the destination terminal 22 as the incoming call signal 28. The destination terminal 22 prepares to communicate using the time slot, and returns a signal with the same content as a response signal 29 to the exchange 20.
establishes a path within the network at 8 kb/s and sends a connection completion signal 30 to the originating terminal 19. The connection completion signal 30 includes information to use a communication speed of 8 kb/s. If communication is possible at the communication speed, the originating terminal 19 communicates with the destination terminal at the communication speed. When communication is not possible due to the communication speed, or after the communication is completed, a disconnection request signal 32 is sent to the exchange 20 to disconnect the call.

If the exchange 20 does not have detailed information on the B channel to be used (for example, time slot number, usable communication speed of the terminating terminal, etc.), the terminating terminal 2
The receiving terminal 22 includes the communication speed designation information specified by the calling terminal in the incoming call signal 28 to the call signal 28, determines the communication speed, and sends detailed B channel information including the communication speed and the time slot to be used in the response signal 29.
By sending the data in the same manner as above, it is possible to perform speed matching in the same manner as described above.

(b) Multiple speed specification...The originating terminal 19 specifies multiple communication speeds (for example, 18, 16, 32kb/s).
3 channels) and include it in the calling signal 27 along with the used time slot number to the exchange 20.
The exchange 20 or the destination terminal 21 selects the communication speed (for example, 16 kb/s), and if the exchange 20 selects the incoming call signal 28, and if the destination terminal 21 selects it, the response signal 29 indicates the applicable speed. The data is sent to the selected communication speed and used time slot number, and thereafter communication is performed at the selected communication speed in the same manner as described above.

(c) Maximum speed specification: The originating terminal 19 specifies the maximum speed (for example, 32 kb/s) of an empty time slot that can be used in one B channel time slot, and sends it in the calling signal 27. Exchange 2
0 or the destination terminal 22, the communication speed of the destination terminal (less than the specified maximum speed) (e.g.
8kb/s) and the time slot to use. If selected by the exchange 20, the incoming call signal 28
If selected by the receiving terminal 22, the above information is included in the response signal 29, and thereafter communication is performed at the corresponding speed in the same manner as described above. Of course, the exchange (or switching network) 20 provides an intra-network transmission path at the finally determined communication speed. Therefore, for example, as shown in Figure 3b,
If a communication speed of 8kb/s is selected,
An 8 kb/s intra-network path is established and the remaining transmission capacity can be used for other calls.

Which of the above three speed designation methods to use can be arbitrarily set depending on the configuration of the applied communication system, the call occurrence situation, etc. It is possible to use a different speed designation method for each terminal, and it is also possible to use an arbitrary speed designation method even for the same terminal depending on the state at the time of calling.

As described above, in the present invention, the originating terminal makes a call by specifying one or more communication speeds or the maximum communication speed, and the exchange or destination terminal selects the available communication speed of the destination terminal. The exchange adopts a method of matching the communication speed between the originating and destination terminals and the intra-network path by setting the path within the network according to the selected communication speed and notifying the originating terminal of the communication speed. Therefore, by negotiating the communication speed between the terminal, network, and terminal during the call control procedure when making a call, the originating terminal can easily adjust the communication speed without being aware of the communication speed or channel usage status of the destination terminal. Can be matched. If applied to a communication system such as an ISDN subscriber system where one communication channel can be divided and used to provide multiple communication speeds,
Flexible communication speed matching is possible with a simple procedure, and transmission lines can be used economically.

[Brief explanation of drawings]

Fig. 1 is a diagram for explaining an example of a conventional speed matching method, and Fig. 2 is an example of the use of divided communication channels for a terminal that can communicate at multiple communication speeds by dividing the communication channel of a subscriber line. Figure 3a is a diagram showing an example of the relationship between the communication speed of the intra-network transmission path and the effective communication speed according to the conventional method, and Fig. 3b is a diagram showing the intra-network path and the effective communication speed when speed matching is performed according to the present invention. FIG. 4 is a block diagram showing an example of the configuration of a digital communication system to which the speed matching communication method of the present invention is applied, and FIG. 5 is a diagram showing the relationship between communication speeds of terminals. FIG. Diagram showing an example of a configuration and a divided use configuration within a channel, No. 6
The figure is a diagram showing an example of a sequence of a rate matching control procedure within a call setup procedure in an embodiment of the present invention. In the figure, 1, 4, 16, 19, 21, 22
... terminal, 2, 20 ... exchange, 3, 23 ... subscriber line, 5 ... speed switching request signal, 6 ... channel assignment signal, 7, 27 ... calling signal, 8, 28 ...
...Incoming call signal, 9,29...Response signal, 10,30
... Connection completion signal, 11, 31 ... Communication signal, 1
2, 32...Disconnection request signal, 13,33...Disconnection instruction signal, 14,15,34,35...Disconnection confirmation signal, 17,25...Speech channel, 18,26
... Call control channel, 24 ... Signal processing device.

Claims (1)

[Claims] 1. A terminal device that allows selection of multiple communication speeds,
A communication system comprising a switching network including one or more exchanges that connects, disconnects, etc., and controls these transmission paths with a counterpart terminal in response to a connection request from a terminal device, the switching network and one or more terminal devices; A subscriber line consisting of a communication signal channel consisting of a plurality of time slots and a call control signal channel is used to connect the terminal to the exchange. The network or the terminating terminal determines that, among the communication speeds selectable by the terminating terminal, there are a number of free time slots in the communication signal channel of the subscriber line on the terminating terminal side that can realize the communication speed specified by the originating terminal. In this case, the specified communication speed,
In addition, if the number of free time slots that can achieve the communication speed specified by the originating terminal does not exist in the communication signal channel of the subscriber line on the receiving terminal side, the communication speed that can be achieved when all the free time slots are used is A speed matching communication method is characterized in that the originating terminal is notified, and the originating and terminating terminals communicate at a communication speed that allows communication.