JP3511224B2 - Voice compression switching system and switching control method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voice compression / switching system and a switching control method for controlling switching connection of a voice signal or a facsimile signal which has been compressed. Various systems have been proposed as a voice compression / switching system for effectively utilizing a digital relay line by performing voice compression and multiplexing. However, there is a drawback that the time required for the exchange processing such as the capture processing of the voice compression trunk becomes long, and this improvement is desired.

[0002]

2. Description of the Related Art FIG. 10 is an explanatory diagram of a conventional voice compression switching system, in which 101, 102 and 103 are stations A and B.
Station, switch of C station, 104, 111, 112, 126 are telephone terminals (TEL), 105, 113, 127 are facsimile terminals (FAX), 106 is a voice compression trunk (16k) for performing voice compression and expansion at 16 kbps, 107
Is a voice compression trunk (32k) for performing voice compression and expansion to 32 kbps, and 108, 109, 117 and 122 are I
SDN trunk trunk, 110 high-speed digital network, 1
14 and 123 are voice compression trunks (8k) that perform voice compression and expansion at 8 kbps, and 115 and 124 are 16 kbp.
A voice compression trunk (16
k), 116, 125 are voice compression trunks (32k), 118, 121 for performing voice compression and expansion at 32 kbps.
Is a digital trunk trunk, 119 and 120 are TDM
It is a device.

The number of the telephone terminal 104 accommodated in the A station is AAAA-2000, the number of the facsimile terminal 105 is AAAA-6000, and the telephone terminal 1 accommodated in the B station.
Numbers 11 and 112 are BBBB-2000 and BBBB-
2001, the number of the facsimile terminal 113 is BBBB-
6000, the number of the telephone terminal 126 accommodated in the C station is CCCC-2000, the number of the facsimile terminal 127 is CCCC-6000, and the 2000s are telephone terminals,
The 6000 range shows the case of a tall dial system in the form of numbers used as a facsimile terminal.

A voice signal is sampled at 8 kHz to obtain 8
If the digital signal has a bit structure, it becomes a digital voice signal of 64 kbps. This audio signal is 8 kbps
When the compression processing is performed, the 8 multiplexed audio signal can be transmitted to the 64 kbps line. Therefore, when the voice compression trunks 114 and 123 are captured, the voice signals for eight lines are multiplexed and transmitted.
When 06, 115, and 124 are captured, the voice signals for four lines are multiplexed and transmitted, and the voice compression trunk 10
When 7,116,125 are captured, the audio signals for two lines can be multiplexed and transmitted.

The route a _{1 between the A} and B stations and the route c ₁ between the B and C stations are ISDN relay lines and are 64 kbps × n.
It is a digital line of the band. The route c between stations B and C
₂ is 64 kbps via the TDM devices 119 and 120
It is a digital line with a band of × n.

FIG. 11 is a partial detailed explanatory view of a conventional voice compression switching system. The same reference numerals as those in FIG. 10 denote the same parts, and 118 ₁ , 118 ₂ , 121 ₁ , 121 ₂ are digital trunk trunks. 131 to 136 are multiplexing / demultiplexing units, 137 and 140 are 8 kbps compression / decompression units, 13
8,141 is a 16 kbps compression / decompression unit, 139,1
42 is a 32 kbps compression / expansion unit, and 143 and 144 are 32 kbps compression / expansion units according to the ADPCM system.
Reference numerals 45 and 146 denote non-compression parts.

The voice compression trunks 114 and 123 have, for example, VSELP at the compression / expansion units 137 and 140.
(Vector Sum Excited Linear Prediction) system and LD-CELP (Low Delay Code Excited)
Audio compression to 8 kbps by the Linear Prediction method or the like, 8 lines are multiplexed by the multiplexing / demultiplexing units 131 and 134 into a 64 kbps digital signal, and demultiplexed to 8 lines by the multiplexing / demultiplexing units 131 and 134.
The compression / decompression units 137 and 140 respectively perform decompression processing that is the reverse of the compression processing, resulting in 8 kbps to 64 kbps.
Then, the digital voice signal or the analog voice signal by DA conversion is transmitted to the telephone terminals 111 and 126.

16 kbps or 32 kbps voice compression trunks 106, 107, 115, 116, 124, 1
25, for example, LD-CELP and ADPCM
A compression process, a multiplexing process, a demultiplexing process, and a decompression process of audio signals for four lines or two lines according to the method are performed.

The TDM devices 119 and 120 are ADPCs.
It is provided with compression / decompression units 143 and 144 for compressing or decompressing to 32 kpbs by the M method, and non-compression units 145 and 146 for transmitting with a bandwidth of 64 kbps, for time division multiplexing and demultiplexing. is there.

The voice signal from the telephone terminal is 8 kbps,
It is compressed and multiplexed at a compression rate of either 16 kbps or 32 kbps, or transmitted in an uncompressed band of 64 kbps. On the other hand, the G3 facsimile signal by the facsimile terminal is compressed and transmitted in the uncompressed band of 64 kbps or 32 kbps by ADPCM, and the transmission speed is too slow at 8 kbps or 16 kbps, which is not practical and is not adopted. It will be.

Therefore, between the telephone terminal 111 accommodated in the B station and the telephone terminal 126 accommodated in the C station, the voice compression trunks 114 to 116, 123 to 125 or the digital trunk trunks 118 ₁ and 118 _{2 are provided.} , 12
Either 1 ₁ or 121 ₂ is captured to form a speech path. Further, between the facsimile terminal 113 accommodated in the B station and the facsimile terminal 127 accommodated in the C station, the TDM
Digital trunk trunks 118 ₁ , 118 ₂ , 12 to be connected via compression / expansion sections 143, 144 or uncompressed sections 145, 146 of devices 119, 120.
Either 1 ₁ or 121 ₂ is captured.

There is also known a system in which voice signals are compressed and facsimile signals are uncompressed and multiplexed (for example, see Japanese Patent Laid-Open No. 2-92091). In this case, the communication bandwidth designation signal from the terminal is identified in the exchange, the voice signal from the telephone terminal is connected to the input port of the band compression circuit of the multiplexer, and the facsimile signal from the facsimile terminal is It controls the exchange to connect to the compression input port. That is, a voice signal and a facsimile signal are discriminated from each other by a designated signal, and compression processing or non-compression processing is selected. It is necessary to add a communication bandwidth designation signal and to have a detection function for it. It cannot support the compression rate of.

In addition, the compression rate of the voice signal is controlled so that the calling side and the receiving side are matched, and if they are not matched, the means for converting the compression rate to match the compression rate only once is interposed. A method of performing compressed communication is known (see, for example, Japanese Patent Laid-Open No. 61-290843). In this case, the relay connection between the exchanges having a plurality of types of compression rates is made possible by passing through the relay exchange provided with the voice compression algorithm conversion unit, and quality deterioration due to repeated compression / expansion is prevented. It does not show a control method for selecting a plurality of compression rates and connecting them to each other.

[0014]

The above-mentioned FIG. 10 or FIG.
In the voice compression switching system shown in FIG. 1, for example, when the telephone terminal 126 of the C station calls the telephone terminal 104 of the A station, the 8 kbps voice compression trunks 123 and 114 are captured at the C and B stations. , When sending a trunk line to station A using a compression rate of 8 kbps, station A outputs 8 kbp
s voice compression trunk is not provided, so station A to N
The G response signal will be received.

Therefore, the station B captures the voice compression trunk 115 having a different compression rate, for example, 16 kbps,
A relay line will be sent to station A. In this case, the station C can also be instructed to reacquire the 16 kbps voice compression trunks to acquire the 16 kbps voice compression trunks 115 and 124 having the same compression rate. As described above, when the opposite side is not provided with the voice compression trunk having the same compression rate as the own station side, there is a problem that it takes a long time to mutually capture the voice compression trunks having the same compression rate.

Further, for example, telephone terminals 11 of stations B and C
After making a call between 1 and 126, the facsimile terminal 11
When performing facsimile communication between 3 and 127, the call between the telephone terminals 111 and 126 is 8 kbps or 1
6 kbps voice compression trunk 114, 123 or 11
If 5, 124 are captured and connected via the route c ₁ , G will be sent to the facsimile terminals 113, 127.
In order to enable 3 facsimile communication, the trunk grouping is performed and the route c ₂ for performing the uncompressed process or the compressed process of 32 kbps is selected, and the different route is used for the voice signal and the facsimile signal. It was necessary to perform selective connection control of the paths c ₁ and c ₂ .

When the line cost is related to the distance between the stations, for example, the distance between the A and B stations is longer than that between the B and C stations, and the 16 kbps voice compression trunk 11 of the B and C stations is used.
When all 5 and 124 are in use, even if the 16 kbps voice compression trunk 106 of the A station has a vacancy, the 32 kbps voice compression trunks 107 and 116 between the B and A stations.
Will be captured. That is, it is difficult to reduce the line cost because the multiplicity of the long-distance line cannot be increased as compared with the short-distance line. SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the conventional example, shorten the connection time, and enable the voice compression switching control with good line efficiency.

[0018]

A voice compression / switching system of the present invention will be described with reference to FIG. 1. (1) In a switching system in which a plurality of switches are connected by digital lines, the switches are compressed. Voice compression trunks 2-1 to 2-1 having a single or a plurality of compression rates for performing multiplexing and demultiplexing / decompression.
2-3 and the terminals 7, 8 or the digital line 9 or the terminal and the digital line via the voice compression trunks 2-1 to 2-3 or without the voice compression trunks 2-1 to 2-3. A network switch unit 3 for performing an exchange connection between the two, a connection condition storage unit 4 storing connection condition data including connection availability for each route, and a minimum compression rate corresponding to a terminal or a trunk group. The network switch unit 3 is controlled by referring to the compressed rate storage unit 5 and the data stored in the connection condition storage unit 4 and the compression rate storage unit 5, and a compression rate that is equal to or higher than the minimum compression rate and that satisfies the connection condition data. And a control unit 6 connected by. Reference numeral 10 denotes an ISDN trunk trunk, and the connection condition storage unit 4 and the compression rate storage unit 5 can identify the available compression rate with the game and control the connection.

Further, (2) the connection condition storage unit 4 is composed of a connection condition data table storing connection condition data indicating connection availability for each compression rate, and the compression rate storage unit 5 stores dial analysis data. It consists of a dial analysis data table that stores the corresponding minimum compression rates.

(3) The compression rate storage unit 5 can be constructed by a terminal class data table storing the minimum compression rate corresponding to the extension number.

Further, (4) the compression rate storage unit 5 can be constituted by a trunk group class data table storing the minimum compression rate for each incoming route.

(5) A voice compression trunk connection control table storing the preset maximum number of connections and the current number of connections of voice compression trunks corresponding to the compression rate can be provided for each route.

(6) In the exchange control method of the present invention, the voice compression trunks 2-1 to 2-1 having single or plural types of compression rates are used.
In a switching control method in which a plurality of exchanges equipped with -3 are connected by a digital relay line and communication is performed by voice compression / multiplexing, a connection in which connection condition data indicating whether or not a compression rate can be connected is stored for each route Prepare a condition data table and a dial analysis data table that stores the minimum compression rate corresponding to the dial analysis data, extract the connectable compression rate of the route selected according to the dial information when making a call from the connection condition data table, and A process of extracting a minimum compression rate according to the dial analysis data obtained by analyzing dial information from the dial analysis data table, and capturing and connecting a voice compression trunk that is equal to or higher than the minimum compression rate and satisfies the selected route connection condition. Is included.

(7) An exchange in which a plurality of exchanges provided with voice compression trunks 2-1 to 2-3 of single or a plurality of types of compression rates are connected by a digital relay line and communication is performed by voice compression multiplexing. In the control method, a connection condition data table that stores connection condition data indicating whether or not a compression rate can be connected for each route, and a terminal class data table that stores the minimum compression rate allowable for the accommodated terminal are prepared. However, the connectable compression rate of the route selected according to the dialing information at the time of the call is extracted from the connection condition data table, and the minimum compression rate allowable for the calling terminal is extracted from the terminal class data table. It also includes the step of capturing and connecting a voice compression trunk that satisfies the connection condition of the selected route.

(8) Exchange in which a plurality of exchanges equipped with voice compression trunks 2-1 to 2-3 having a single or a plurality of types of compression rates are connected by a digital relay line and communication is performed by voice compression multiplexing. In the control method, a connection condition data table that stores connection condition data indicating whether or not a compression rate can be connected for each outgoing route, and a trunk group class data table that stores the minimum allowable compression rate for each incoming route. Prepare, extract the minimum allowable compression rate for each incoming route from the trunk group class data table, select a compression rate that is equal to or higher than this minimum compression rate and satisfies the outgoing route connection condition, and respond to this compression rate. It involves capturing and connecting a voice compression trunk.

(9) A voice compression trunk connection control table showing the maximum number of compression rate-compatible trunks that can be connected for each outgoing route and the number of current connected trunks is prepared, and the current connected trunk is selected when the outgoing route is selected. The process may include capturing and connecting voice compression trunks of this compression rate, provided the number has not reached the maximum number of trunks.

[0027]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is an explanatory view of a main part of a voice compression switching system according to an embodiment of the present invention, in which 1 is a digital exchange, 2-1 is band-compressed to 8 kbps and multiplexed,
And an 8k voice compression trunk that expands the demultiplexed 8kbps to 64kbps, 2-2 band-compresses to 16kbps and multiplexes, and demultiplexed 16kbps to 64
16k voice compression trunk which expands to kbps, 2-3 band-compresses to 32 kbps and multiplexes, and 32k voice compression trunk which expands demultiplexed 32 kbps to 64 kbps, 3 is a network switch unit, 4 is a connection condition storage unit, 5 is a compression rate storage unit, 6 is a control unit, 7 is a telephone terminal (TEL), 8 is a facsimile terminal (FAX),
Reference numeral 9 indicates a line, and 10 indicates an ISDN trunk trunk.

A high-speed digital line connected via the ISDN trunk 10 is, for example, 64 kbps ×
It has n bands and is connected to another digital exchange (not shown). Also, the voice compression trunks 2-1 to 2-3 are
For example, as shown in FIG.
It has a configuration including a separation unit, is captured by the control of the control unit 6, and is connected to the telephone terminal 7, the facsimile terminal 8, the line 9, the ISDN trunk trunk 10, etc. via the network switch unit 3.

The connection condition storage unit 4 stores connection condition data including the compression condition for each route, and the compression rate storage unit 5
Is configured to store a compression rate corresponding to a terminal or the like, and can be formed in, for example, a main memory (not shown) or the control unit 6. The control unit 6 includes a processor and the like, and includes the connection condition storage unit 4 and the compression rate storage unit 5
Based on the contents of and, the voice compression trunk of the same compression rate of the own station and the opposite station is captured, the network switch unit 3 is controlled, and the terminals are connected at the compression rate of the minimum compression rate or more. Become.

FIG. 2 is an explanatory view of the first embodiment of the present invention, in which 11, 12, 13 are exchanges for stations A, B, and C, 14, 21, 22, 29 are telephone terminals, and 15 is a telephone terminal. , 23,
Reference numeral 30 is a facsimile terminal, 16 is a 16 kbps voice compression trunk (16k), 17 is a 32 kbps voice compression trunk (32k), 18, 19, 27 and 28 are ISDs.
N trunk trunk, 20 is high-speed digital network, 24,3
1 is 8 kbps voice compression trunk (8k), 25 is 1
6 kbps voice compression trunk (16k), 26, 32
Is a 32 kbps voice compression trunk (32 k), 33 is a control unit (CC), 34 is a connection condition data table as a connection condition storage unit, and 35 is a dial analysis data table as a compression rate storage unit.

The station numbers of stations A, B and C are set to AAA.
A, BBBB, CCCC, telephone terminals in the 2000s, facsimile terminals in the 6000s, the destination dial of the dial analysis data table 35 uses the station number and the first digit of the telephone number, and stores the minimum compression rate. . For example, in the dial analysis data table 35 of the control unit 33 of station B, station A has 16 kbps and 32 kbps.
Since the voice compression trunks 16 and 17 for ps are provided, 16 kbps is stored as the minimum compression rate of AAA-2 of the destination dial. Further, since the station C is provided with the voice compression trunks 31 and 32 of 8 kbps and 32 kbps, 8 kbps is stored as the minimum compression rate of CCCC-2 of the destination dial. The destination dials AAA-6 and CCCC-6 are for facsimile terminals, and 32 kbps is stored as the minimum compression rate.

The connection condition data table 34 is provided for each route a ₁ to the B station or A station or for each route c ₁ from the B station to the C station.
The connection availability corresponding to the compression rate is stored. For example, for route a ₁ , station A does not have a voice compression trunk of 8 kbps, so the compression rate of 8 kbps cannot be connected, and the compression rates of 16 kbps and 32 kbps can be connected. Further, since the station C does not have a voice compression trunk of 16 kbps, the compression rate of 16 kbps cannot be connected, and the compression rates of 8 kbps and 32 kbps can be connected.

The contents of the connection condition data table 34 and the dial analysis data table 35 described above can be stored based on station data and the like when the switching system is started up. Further, the contents of the connection condition data table 34 and the dial analysis data table 35 can be updated in response to the addition or removal of voice compression trunks during system operation. Further, although the case where the connection condition data table 34 and the dial analysis data table 35 are formed in the control unit 33 is shown, the connection condition data table 34 and the dial analysis data table 35 may be formed in the main memory (not shown) controlled by the control unit 33. The same control unit 33 and connection condition data table 3 are also used in stations A and C.
4 and the dial analysis data table 35.

FIG. 3 is a flowchart of the first embodiment of the present invention. For example, the BBBB-2000 telephone terminal 21 accommodated in the B station in FIG. 2 to the CCCC-accommodated in the C station. When a call is made to the 2000th telephone terminal 29, dial information (CCCC-2000) is extracted (A1). In this case, on the outgoing side of the station B, the route c _{1 that} can be connected to the station C by the extracted dial information.
(A3). Then, by searching the connection condition data table 34, route c ₁ connectable compression rate (8
kbps, 32 kbps) is extracted (A4).

On the entrance side to which the extension terminal of station B is connected,
The extracted dial information (CCCC-2000) is analyzed to extract the minimum compression rate (A2). By searching the dial analysis data table 35 with CCCC-2 of the dial analysis data in this case, it is possible to identify that the minimum compression rate is 8 kbps.

Then, the minimum compression rate (8 kbps) extracted in step (A2) and step (A4)
Compression rate that can be connected and extracted in (8 kbps,
32 kbps), the voice compression trunk of the route determined in step (A3) is selected (A5), and it is determined whether or not this voice trunk can be captured (A6).
If an empty voice compression trunk exists (OK), the voice compression trunk is captured and route connection is made (A9). In this case, the voice compression trunks 24 and 31 of 8 kbps having the minimum compression rate are captured, and the telephone terminals 21 and 29 are connected via the ISDN trunk trunks 27 and 28 of the route c ₁ .

If there is no empty voice compression trunk having the minimum compression rate (8 kbps) (NG), the minimum compression rate is updated (A7). In this case, 8 → 16 → 3
It is updated in the order of 2 → 64 (kbps), but the minimum compression rate is updated from 8 → 32 (kbps) based on the connection availability condition for each route c ₁ of the connection condition data table 34. Next, the updated minimum compression rate is 64 kbp
It is determined whether s has been reached (A8), and if it has not reached 64 kbps, the process proceeds to step (A5), where 64 kb
When it reaches ps, the route connection is performed by the non-compression processing (A9).

If the voice compression trunk cannot be captured even by updating the minimum compression rate, the minimum compression rate will be updated in step (A7). In this case, the minimum compression rate is updated from 32 to 64 (kbps), so in step (A8) the minimum compression rate is 64 kbps, and the uncompressed 64 kbps band is obtained without capturing the voice compression trunk. , The telephone terminals 21 and 29 are connected.

Further, in FIG. 2, the BBB accommodated in the B station
When transmitting a facsimile signal from the facsimile terminal 23 of B-6000 number to the facsimile terminal 30 of CCCC-6000 accommodated in the C station, the B station dials the dial information (CCCC-60 according to step (A1)).
00), the route c ₁ for station C is determined according to step (A3), and the connectable compression rate is extracted by referring to the connection condition data table 34 according to step (A4).

Then, according to step (A5), it is possible to identify that the minimum compression rate is 32 kbps based on the dial analysis data and the connection condition data.
If the voice compression trunks 26 and 32 of kbps are captured and the facsimile terminals 23 and 30 are connected, and if there is no space in the voice compression trunk, the minimum compression rate is 64 kbps in step (A7). And the facsimile terminals 23 and 30 are connected by non-compression processing according to the determination in step (A8).

FIG. 4 is an explanatory view of the second embodiment of the present invention, showing the B station and the C station, and the same symbols as those in FIG. 2 indicate the same parts. In the figure, 37 and 38 are digital trunk trunks, 39 and 40 are TDM devices, 41 is a connection condition data table corresponding to the connection condition storage unit 4 (see FIG. 1), and 42 is a compression rate storage unit 5 ( 2 is a terminal class data table corresponding to (see FIG. 1).

The connection condition data table 41 has the same structure as the connection condition data table 34 in FIG. 2, but the connection condition data in this case is 16 kbps for the B station.
Since it does not have a voice compression trunk, the routes c ₁ , c
The connection availability of 16 kbps for each ₂ is not available. Further, the terminal class data table 42 stores the minimum compression rate corresponding to the connection extension number. For example, the minimum compression rate of extension numbers 2000 and 2001 is 8 kbps,
The minimum compression rate for extension number 6000 is 32 kbps.

FIG. 5 is a flow chart of the second embodiment of the present invention. For example, the telephone terminal 21 of BBBB-2000 to the telephone terminal 2 of CCCC-2000 of the C station.
When making a call to station 9, station B extracts the originating terminal class (B1), and extracts the minimum compression rate from the terminal class data according to the originating terminal class (B2). That is, the terminal class data table 42 is searched by converting to the extension number according to the accommodation position information of the telephone terminal 21 of the calling terminal. In this case, the extension number is 2 from the accommodation position information of the telephone terminal 21.
It can be identified as 000 and its extension is 2000
It can be seen that the minimum compression rate of is 8 kbps.

On the outgoing side, dial information (CCCC-2
000) is extracted (B3), and the connectable route (c ₁ ) is calculated from this dial information (B4). Then, the connectable compression rate (8 kbps, 3) of this route (c ₁ )
2 kbps) is extracted from the connection condition data table 41 (B5). This connectable compression rate (8 kbps,
32 kbps) and the minimum compression rate (8 kbps) based on the terminal class data, an 8 kbps voice compression trunk 24 is selected (B6), and it is determined whether or not this voice compression trunk can be captured (B7). If it can be captured, the route connection is established between the telephone terminals 21 and 29 in the band of 8 kbps (B10).

If there is no available voice compression trunk and it cannot be captured, the minimum compression rate is updated (B8), and it is determined whether the updated minimum compression rate is 64 kbps (B8).
9) If not 64 kbps, the process proceeds to step (B6), and if 64 kbps, proceeds to step (B10).

In this case, the connectable compression rates extracted from the connection condition data table 41 are 8 kbps and 32.
kbps, which is 32 kbps by updating the compression rate of 8 kbps, and the voice compression trunk of 32 kbps is captured. Also in this case, when there is no empty voice compression trunk, the minimum compression of step (B8) is performed. The rate is updated to 64 kbps, and the minimum compression rate is 64 kbps in step (B9).
According to the determination, the process shifts to step (B10), and the telephone terminals 21 and 29 are connected by the non-compression process.

Further, the 6000th facsimile terminal 2 of station B
Dial CCCC-6000 from 3 to 6
When calling to the 000th facsimile terminal 30, the terminal class data table 42 is searched by the extension number 6000 and it is found that the minimum compression rate is 32 kbps.

The extracted dial information (CCCC-60
00) causes the control unit 33 to determine the route c ₁ or c ₂ to the station C.
And the route c ₁ is selected, the connection permission / prohibition of the route c ₁ of the connection condition data table 41 is searched. In this case, 8 kbps and 32 kbps will be extracted. Since the minimum compression rate of 32 kbps is read from the terminal class data table 42, the 32 kbps voice compression trunk 26 is captured.

When the route c ₂ is selected, the connection condition data table 41 is searched for the connection possibility corresponding to the compression rate of the route c ₂ . In this case, since only 32 kbps can be connected, the digital trunk line trunk 37 is captured and
The band is compressed to 32 kbps by the ADPCM in the DM device 39, and the facsimile communication is performed. Also C
Connection control information and the like can be transmitted from the B station to the station by a common signal line system or the like.

FIG. 6 is an explanatory view of the third embodiment of the present invention, in which the same reference numerals as those in FIGS. 2 and 4 indicate the same parts.
3 is a 16 kbps voice compression trunk (16k), 4
7, 48 are digital trunk trunks, 49, 50 are T
The DM device, 51 is a connection condition data table corresponding to the connection condition storage unit 4 (see FIG. 1), and 52 is a trunk group class data table corresponding to the compression rate storage unit 5 (see FIG. 1). The connection condition data table 51 stores data of connection availability corresponding to the compression rate for each of the routes a ₁ and c ₁ . Moreover, trunk group class data table 5
2 stores the minimum compression rate corresponding to the incoming route.

FIG. 7 is a flow chart of the third embodiment of the present invention. For example, when a telephone terminal 14 of AAA-2000 of station A calls a telephone terminal 29 of CCCC-2000 of station C. At station A, it is possible to identify that station B, which is the opposite station, is equipped with a 16 kbps voice compression trunk 25. Therefore, CCCC-200 of dial information is used.
If 0 is extracted and route a ₁ is selected, for example, at station B, since the incoming route is a ₁ , the trunk group class of the incoming route is extracted (C1) and this trunk group class is extracted. The trunk group class data table 52 is searched by and the minimum compression rate corresponding to the incoming route is extracted (C2). In this case, the trunk group class data table 52 is set to the entrance route a ₁
By searching with, the minimum compression rate is 16 kb
It turns out that it is ps.

Also, dial information (CCCC-2000) is extracted (C3), and this dial information (CCCC-200) is extracted.
0) is used to determine the outgoing route (C4), and the connection condition data table 51 is searched to extract the connection availability of the compression rate for each outgoing route. In this case, the route c ₁ is set by the dial information, and it is understood that the connectable compression rate of the route c ₁ is 16 kbps.

The minimum compression rate of the route a ₁ is 16
kbps and a compression rate of 16k that allows connection of the route c ₁
Determine the voice compression trunk based on bps (C6),
It is judged whether or not this voice compression trunk can be captured (C
7) When it can be captured (OK), the route a ₁ and the route c ₁ are connected using the 16 kbps voice compression trunk 25 (C10).

When the voice compression trunk cannot be captured (NG), the minimum compression rate is updated (C8), and it is determined whether the updated compression rate is 64 kbps (C9), 6
If it is not 4 kbps, move to step (C6),
In the case of 64 kbps, the process proceeds to step (C10), and the connection is made in the uncompressed 64 kbps band.

When the facsimile terminal 15 of AAA-6000 of station A sends a call to the facsimile terminal 30 of CCCC-6000 of station C and station A selects route a ₂ , station B selects trunk group class. The data table 52 is searched by the input route a ₂ , and the minimum compression rate is 32 kbps.
Dial information extracted or extracted (CCCC-600
0), select the route c ₁ to C station, and select this route c
_The connection condition data table 51 is searched for a connectable compression rate of ₁ . In this case, since the compression rate of 32 kbps cannot be connected, the compression rate is set to 64 kbps.
Without capturing the voice compression trunk 25,
Connect to route c ₁ .

FIG. 8 is an explanatory diagram of the fourth embodiment of the present invention. The same reference numerals as those in FIGS. 2, 4 and 6 denote the same parts, and 53 is a voice compression trunk connection control table.
The maximum connection trunk number and current connection trunk number of voice compression trunks corresponding to the compression rate are stored for each route. When the number of currently connected trunks exceeds the set maximum number of connected trunks, the control unit 33 refuses to capture the voice compression trunk of the route, updates the minimum compression rate, and updates the voice of the updated compression rate. It will capture the compressed trunk.

For example, in a station B equipped with twelve 16 kbps voice compression trunks 25, if the distance to the station A is longer than the distance to the station C, the route a to the station A is used.
The maximum number of connections trunk ₁ can set the maximum number of connections trunk route c ₁ for 8, C station 4. Since the voice compression trunks of 8 kbps and 32 kbps are not provided, 8 kbps and 3 for each of the routes a ₁ and c _1.
The maximum number of connection trunks with 2 kbps is set to 0.

FIG. 9 is a flowchart of the fourth embodiment of the present invention. For example, from the telephone terminal 21 to CCCC-
When the call is made to the 2000th telephone terminal 29, the dial information (CCCC-2000) is extracted (D1), the voice compression trunk and the outgoing route to be connected are selected (D2), and the voice compression for each outgoing route is performed. Extract the maximum number of connected trunks (D3), compare the current connected trunk number with the maximum connected trunk number (D4), and if the current connected trunk number is smaller than the maximum connected trunk number, capture the voice compression trunk Then, the number of currently connected trunks in the voice compression trunk connection control table 53 is incremented by 1 (D7), and the route connection is performed through the voice compression trunk (D8).

In the above case, dial information (CCCC-2
000), the minimum compression rate of the route c ₁ and 16 kbps is selected, and the voice compression trunk connection control table 5
If the maximum number of connection trunks of the 16 kbps voice compression trunk of the route c ₁ of 3 is 8 and the number of current connection trunks is 4,
Since the condition of the current connection number <maximum number in step (D4) is satisfied, the current connection trunk number is incremented by +1 (= 5), and the telephone terminals 21 and 29 are connected via the voice compression trunk.

In step (D4), the current number of connections <
If the maximum number of conditions is not met, for example, ₁ of the route c 1
Number of currently connected trunks of 6 kbps voice compression trunks
In the case of, the minimum compression rate is updated (D5). In this case, since the voice compression trunk of 32 kbps is not provided, it is updated to 64 kbps, and the connection between the telephone terminals 21 and 29 is performed in the uncompressed band of 64 kbps. Although not shown, the number of currently connected trunks is unconditionally decremented by -1 when the call ends, and it can be combined with any of the first to third embodiments.

The present invention is not limited to the above-mentioned respective embodiments, and the respective embodiments can be combined,
The present invention can be applied to various voice compression / switching systems for improving the efficiency of line utilization by voice compression / multiplexing transmission. See also FIG.
For a voice compression trunk with a certain compression rate in
It is also possible not to set the maximum number of connection trunks for a specific route, and in this case, all the voice compression trunks of a certain compression rate can be used for the route.

[0062]

As described above, according to the present invention, in the voice compression exchange system and the exchange control method thereof in which the utilization efficiency of the line is improved by the compression multiplexing, the connection condition storage unit 4 is used.
And a compression rate storage unit 5 are provided, the connection possibility corresponding to the compression rate for each route is determined by the data stored in the connection condition storage unit 4, and permitted by the data stored in the compression rate storage unit 5. Even if it is a large-scale exchange system, it is possible to determine the minimum possible compression rate and connect to the game at a compression rate that is higher than this minimum compression rate and that satisfies the connection condition of the selected route. There is an advantage that the connection processing time can be shortened.

Further, even when band compression is limited in facsimile communication or the like, it is possible to capture a voice compression trunk having a compression rate which does not deteriorate the communication quality based on the set minimum compression rate. That is, the exchange control between the voice terminal and the facsimile terminal can be performed by the same algorithm. Further, by setting the maximum number of connection trunks of the voice compression trunk for each route, there is an advantage that the line cost can be easily reduced when a long distance line is provided.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a main part of a voice compression switching system according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram of the first embodiment of the present invention.

FIG. 3 is a flowchart of the first embodiment of the present invention.

FIG. 4 is an explanatory diagram of a second embodiment of the present invention.

FIG. 5 is a flow chart of a second embodiment of the present invention.

FIG. 6 is an explanatory diagram of a third embodiment of the present invention.

FIG. 7 is a flow chart of a third embodiment of the present invention.

FIG. 8 is an explanatory diagram of the fourth embodiment of the present invention.

FIG. 9 is a flow chart of a fourth embodiment of the present invention.

FIG. 10 is an explanatory diagram of a conventional voice compression exchange system.

FIG. 11 is a partial detailed explanatory diagram of a conventional voice compression switching system.

[Explanation of symbols]

1 Digital exchange 2-1 8k voice compression trunk 2-2 16k voice compression trunk 2-3 32k voice compression trunk 3 Network switch section 4 Connection condition storage section 5 Compression rate storage 6 control unit 7 Telephone terminal (TEL) 8 Facsimile terminal (FAX)

Front Page Continuation (56) References JP-A-4-351097 (JP, A) JP-A-7-1883865 (JP, A) JP-A-7-322377 (JP, A) JP-A-61-290843 (JP , A) JP 5-284136 (JP, A) JP 4-180441 (JP, A) JP 7-226766 (JP, A) JP 4-158659 (JP, A) JP 2-206244 (JP, A) JP-A-2-92091 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H04M 3/00 H04M 3/16-3/20 H04M 3 / 38-3/40 H04M 7/00-7/16 H04Q 3/52 H04Q 11/00-11/08

Claims (9)

(57) [Claims] 1. A switching system in which a plurality of exchanges are connected by digital lines, wherein the exchanges are voice compression trunks of a single or a plurality of compression rates for performing compression / multiplexing and demultiplexing / decompression. Network switch unit for switching connection between terminals or between the digital lines or between the terminal and the digital line via a compression trunk or without the voice compression trunk, and compression rate correspondence for each route Connection condition storage unit that stores connection condition data including connection availability, a compression rate storage unit that stores a minimum compression rate corresponding to each terminal or trunk group, and the connection condition storage unit and the compression rate storage unit. The network switch unit is controlled by referring to the stored data, and the pressure that is equal to or higher than the minimum compression rate and that satisfies the connection condition data is controlled. Audio compression switching system characterized by comprising a control unit connected by rate. 2. The connection condition storage unit is composed of a connection condition data table storing connection condition data corresponding to a compression rate and connection availability for each route, and the compression rate storage unit is a minimum corresponding to dial analysis data. The voice compression switching system according to claim 1, wherein the voice compression switching system comprises a dial analysis data table storing a compression rate. 3. The compression rate storage unit comprises a terminal class data table storing a minimum compression rate corresponding to an extension number.
The voice compression switching system described. 4. The voice compression switching system according to claim 1, wherein the compression rate storage unit is configured by a trunk group class data table storing a minimum compression rate for each incoming route. . 5. A voice compression trunk connection control table storing a preset maximum number of connections and a current connection number of voice compression trunks corresponding to compression rates for each route. Or the voice compression exchange system according to 2. 6. A switching control method for connecting a plurality of exchanges equipped with voice compression trunks of a single or a plurality of types of compression rates by digital relay lines and performing communication by voice compression multiplexing, in each route. A connection condition data table that stores connection condition data that indicates whether the compression rate can be connected and a dial analysis data table that stores the minimum compression rate corresponding to the dial analysis data are prepared, and the route selected according to the dial information when making a call The connectable compression rate of is extracted from the connection condition data table,
A minimum compression rate according to the dial analysis data obtained by analyzing the dial information is extracted from the dial analysis data table, and a voice compression trunk that is equal to or higher than the minimum compression rate and satisfies the selected route connection condition is captured. An exchange control method including a process of connecting. 7. A switching control method for connecting a plurality of exchanges equipped with voice compression trunks of a single or a plurality of types of compression rates by a digital trunk line and performing communication by voice compression / multiplexing, for each route. Prepare a connection condition data table that stores connection condition data that indicates whether or not the compression rate can be connected, and a terminal class data table that stores the minimum compression rate that can be accommodated for the accommodated terminal, and select according to the dial information when making a call. The connectable compression rate of the selected route is extracted from the connection condition data table,
And extracting a minimum compression rate allowable for the calling terminal from the terminal class data table and capturing and connecting a voice compression trunk that is equal to or higher than the minimum compression rate and satisfies the connection condition of the selected route. A characteristic exchange control method. 8. A switching control method for connecting a plurality of exchanges equipped with voice compression trunks of a single or a plurality of types of compression rates by digital trunk lines and performing communication by voice compression multiplexing, wherein an outgoing route is provided. A connection condition data table that stores connection condition data that indicates whether or not a compression rate can be connected for each route and a trunk group class data table that stores the minimum allowable compression rate for each incoming route are prepared. The minimum possible compression rate is extracted from the trunk group class data table, the compression rate that is equal to or higher than the minimum compression rate and satisfies the connection condition of the outgoing route is selected, and the voice compression trunk corresponding to the compression rate is captured and connected. An exchange control method comprising the steps of: 9. A voice compression trunk connection control table showing the maximum number of compression rate-compatible trunks that can be connected for each outgoing route and the number of currently connected trunks is prepared.
9. The method according to claim 6, further comprising a step of capturing and connecting a voice compression trunk of the compression rate on condition that the number of currently connected trunks has not reached the maximum number of trunks. Exchange control method.