JPS6128245A - Transmission system - Google Patents

Abstract

PURPOSE:To allow a reception station side to enter automatically a data reception state by using a data link bit for a multi-frame pattern from the transmission station in the primary group terminal station device of digital transmission and transmitting the information switching a specific channel from the voice transmission to the data transmission to use peg operation of the transmission station. CONSTITUTION:In transmitting voice signals from all channels, each voice signal is coded at a channel panel VF/DCHn and multiplexed at a multiplexer MPXa. When data is desired to be transmitted by using an optional channel (e.g., CH9), a peg (changeover switch) of the channel panel VF/DCH9 of a channel CH9 at transmission side is operated. A voice/data changeover signal is transmitted to a control signal multiplexer MPXb through this operation. Further, the said signal of a data link D is received at the reception station by a control signal multiplex separating device DMPXb to recognize that the channel CH9 changes to data transmission, and it is informed to the channel panel VF/DCH9 to operate the peg.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention is applicable to a communication system using a digital transmission device, in which voice or data is multiplexed and transmitted to an arbitrary channel of a second group terminal device. This relates to the transmission method.

[Conventional technology]

PCM-24, PCM-24B, 30ch are used as primary terminal equipment in communication systems using digital transmission equipment.
North America and Japan are countries where PCM has been introduced, and many PCM voice terminal stations have been introduced worldwide.

In North America, Japan's PCM-24 and PCM-2
Dl and D3 terminal stations corresponding to 4B are used. CCITT Recommendation G in European countries. 732 compliant 3
QchPCM is adopted, which is different from Japan and North America.

The main specifications of the second group terminal equipment are shown in the table below.

Table 3 shows the basic frame structure of Japan's PCM-24B.

That is, as shown in FIG. 3, one frame consists of frame bits F.
(] bits) and 24 time slots TS, each time slot I-TS is composed of 8 bits and represents the audio signal or data signal of each channel.

Further, HG is called a handling group and is composed of 6 channels (6 ([1i1 time slots Ts) i], and therefore one frame is composed of 4 f(G).

FIG. 4 is a diagram illustrating frame bits F of the new 24 multi-frame pattern.

FP in FIG. 4 shows an example of a frame pattern, where the frame bit F of the 4th frame is O1, the frame bit F of the 8th frame is O1, the frame bit F of the 12th frame is 1, and the frame bit of the 16th frame. F is O1 The frame bit F of the 20th frame is 1, and the frame bit F of the 24th frame is I. Synchronization is achieved by detecting (0, 0, 1, 0, 1, 1) of this frame bit F.

The 8th bit of the time slot TS of the 6th and 12th frames is used as a signal bit in the case of audio signal transmission, and is used as data in the case of data transmission.

CRC is a cyclic code that is used for error detection. For example, it performs a check in the format of frame bit F is used.

D corresponds to the frame focus position of odd-numbered frames, and 12
D can be used as a 42 Kb/s data link, or D+D' can be used as a 1)/S data link.

When sending 5END ALM, 11111111, oo
Sends a repeating signal of oooooo.

[Problem that the invention seeks to solve]

Channel C when multiplexing and transmitting voice or data to any channel using the above-next group terminal equipment
Specify in advance whether the Shirakawa channels from HI to CH24 (or CH30) will be used for audio, and which channel will be used for data transmission, and confirm that the channel is used for data transmission by operating a peg, etc. It was clearly stated.

However, this operation naturally requires a discussion between the two terminal stations over the telephone before operating the peg, which has the disadvantage of being inconvenient for the operation of the communication system.

[Interval d) Means for solving the problem]

The solution to this problem is to transmit information for switching a specific channel from audio transmission to data transmission using multi-frame pattern data link bits from the transmitting station in the primary terminal equipment for digital transmission. This is achieved using a transmission method that

[Effect]

According to the present invention, a cheater link bit of a multi-frame pattern is used, and the number of the handling group HG to which the channel to be switched from voice transmission to data transmission belongs and the number within that handling group HG are transmitted to the transmitting station. Since the information can be transmitted to the receiving station side from there, it has the effect of automatically switching any channel from audio transmission to data transmission.

〔Example〕

As explained in the prior art section, there are 12 bits of D allocated for data links, which are used for data links in the case of voice signal transmission, but are not used in the case of data transmission. do not have.

The present invention attempts to utilize this effectively for data transmission.

FIG. 1 is an explanatory diagram showing an embodiment of a transmission system according to the present invention.

The present invention uses the first 8 bits of the 12 bits allocated to data link D.

That is, 1 to 12 in the top row of FIG.
Bits are used to specify HG.

(0, O) specifies 1 to 6 CH, (1, O) specifies 7 to 1
2C) Specify I, (0,1) specifies 13-18cH, and (11) specifies 19-24CH.

The next 6 bits from the 3rd bit to the 8th bit are used to specify the channel within the HG.

For example, if it is 10001000 (indicated by an arrow), the first 10 specifies 7 to 12CH, and the next 00100
0 specifies the third one.

This means that 9CH is used for data transmission.

In this way, by using the 12 bits assigned to data link D, it is possible to inform the other station to which channel data is to be transmitted.

FIG. 2 is a schematic diagram showing an embodiment of the transmission system according to the present invention, where fat indicates the configuration of the transmitting side and (bl indicates the configuration of the receiving side).

In the figure, V F / D CHn is a channel board, n indicates the channel CH number, MPXa is an audio signal or data signal multiplexer, MPXb is a control signal multiplexer, MPX is a coupling device, and SEP is a separation device, DM
PXa is a multiplexing/demultiplexing device for audio signals (or data signals), and DMPXb is a multiplexing/demultiplexing device for control signals.

When all channels transmit audio signals, each audio signal is encoded in the channel board V F /D CHn and multiplexed in the multiplexer M P X a.

Meanwhile, on-hook signal, off-hook signal, dial signal,
And control signals such as billing signals are sent from the channel board VF/
The data is encoded on DCHn, and both are transmitted together to the other station by a coupling device MPX.

On the receiving station side, this signal is received and separated into an audio signal and a control signal by a demultiplexing device SEP, and the audio signal is sent to a multiplexing and demultiplexing device DMPXa, and the control signal is sent to a multiplexing and demultiplexing device for control signals DMPXb. sent and separated.

The coded audio signals in the corresponding channel boards VF/DCHn on the receiving side are restored to analog audio signals, and the control signals are similarly restored and sent to the audio line.

At this time, if you want to transmit data using an arbitrary channel (for example, CH9), select the transmitting side channel CH9.
Channel board VF/DCH9 peg (select switch)
operate.

By this operation, an audio-data switching signal is transmitted to the control signal multiplexer MPXb.

The control signal multiplexer MPXb sets the first 8 pins of the 12 bits assigned to the data link D to 10001000, as described above, and sends it to the partner station via the coupling device MPX.

On the receiving station side, the signal of data link D is received by the control signal demultiplexing device DMPxb, and the signal is transferred to channel C1.
(Identifies that 9 has changed to data transmission, notifies the channel board VF/DCH9 of channel CH9, and operates the peg.

[Effects of the Invention] As described above in detail, the present invention has the great effect that the receiving station can automatically enter the data receiving mode by the peg operation on the transmitting station.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram showing an embodiment of a transmission system according to the present invention. FIG. 2 is a schematic diagram showing an embodiment of the transmission system according to the present invention, in which (al) shows the configuration of the transmitting side and (g) the configuration of the receiving side. Figure 3 shows the basic frame structure of Japan's PCM-24B. FIG. 4 is a diagram illustrating frame bits F of the new 24 multi-frame pattern. In the figure, V F / D CHn is a channel board, n indicates the channel CH number, MPXa is an audio signal (or data signal) multiplexer, MPXb is a control signal multiplexer, MPX is a coupling device, SEP is a separation device, D
M P X a is a demultiplexing device for audio signals (or data signals), and DMPXb is a demultiplexing device for control signals. Plan 1 Kuchi 2 Diagram (α) 3 Plan d

Claims (1)

[Claims] A transmission method, in a primary group terminal equipment for digital transmission, in which information for switching a specific channel from voice transmission to data transmission is transmitted from the transmitting station side using data link bits in a multi-frame pattern.