JPH0758983B2 - Secondary channel method - Google Patents

Description

DETAILED DESCRIPTION [Overview] During transmission of a modem signal, information bits of a secondary channel and a frame synchronization signal are added at a constant cycle, and the frame synchronization signal is changed so that the transmission rate of the modem is constant. The same frame synchronization signal as the speed of the secondary channel is secured, and the error correction code is used for the secondary channel to reduce the transmission error rate.

[Industrial application field]

The present invention relates to voice channel modem secondary channel and frame synchronization.

[Conventional technology]

Secondary channels in voice band modems are often used for network management such as modem remote setting, diagnostics, and line status monitoring. Therefore, secondary channel error rate and other characteristics are better than the main channel. Is required.

The frequency band of the voice line is usually 3100H from 300Hz to 3400Hz
Although there is a width of z, for example, the frequency bandwidth used by a 14.4Kbps modem is less than 3100Hz.

Therefore, in the frequency division method (FDM), this extra band is frequency-divided by a filter, and FSK (Frequency Shift
A secondary channel is realized by using a modulation method such as Keying). Communication speed in this case is usually 75-300b
It is about ps.

FIG. 3 is an explanatory diagram of a conventional secondary channel.

In the figure, M-CH is a main channel, S-CH is a secondary channel, and G is a guard band. The same symbols represent the same objects throughout the drawings.

The main channel M-CH and the secondary channel S-
A guard band G is provided between CHs to eliminate the influence of carrier frequency fluctuations.

However, in the case of a high-speed modem such as 19.2 Kbps, the frequency band used for the main channel becomes wide as shown by the points, so that the frequency band required to realize the secondary channel cannot be obtained by the conventional frequency division method.

If a secondary channel is to be realized by any means, a large-scale and highly accurate filter must be used because the guard band G is narrow, and multilevel PSK (Phase) in order to obtain a certain transmission speed. A complex method such as the Shift Keying method needs to adopt a modulation method, and thus a large-scale circuit is required to create a secondary channel.

In the time division multiplexing method (TDM method), there is also a method of multiplexing secondary channel data in main channel data and transmitting the multiplexed data.

[Problems to be solved by the invention]

However, according to the TDM method, the error rate of the main channel and the error rate of the secondary channel are the same, which is a disadvantage that it is not preferable as the secondary channel.

Further, when the speed of the main channel changes, the speed of the secondary channel also changes, resulting in a change in the frame period.

[Means for solving problems]

The above problem is that in a multi-valued PSK mode modem that uses the voice band and configures the secondary channel by the time division method, the main channel data, the secondary channel data using the error correction code, and the frame bit When one frame is formed and the speed of the main channel changes, the number of modulation bits per symbol and the number of frame bits are changed to keep the cycle of the frame constant and the speed of the secondary channel. Is kept constant by solving.

[Action]

According to the present invention, when the speed of the main channel changes,
By changing the number of modulation bits per symbol and the number of frame bits, it is possible to keep the cycle of the frame constant and the speed of the secondary channel constant.

〔Example〕

FIG. 1 (a) is an explanatory view of the principle of the secondary channel according to the present invention.

As shown in the figure, the structure of one frame according to the present invention includes main channel data (x bits), second channel data (y bits), and frame bits (z bits) in the main channel data of the modem. Are arranged in a time-sharing manner.

It is now assumed that the baud rate is B baud, the number of signal points is 2 ^P (that is, P bits are encoded per symbol), the main channel speed is Rm bps, and the secondary channel speed is Rs bps.

In the present invention, x bit, y bit, and z bit are set so as to satisfy the following conditions.

Condition 1, P ≦ 7, where, P is the number of signal points from the equalization capability of the integer modem 2 ⁷ is the limit.

This is the limit when using a 10% roll-off filter due to condition 2, B ≦ 2785, and band limitation.

However, i and j are integers of 2400 Hz so that they can be synchronized with each other. Therefore, i and j must be as small as possible.

Condition 6, Rs ≧ 110 bps Condition 7, (x + y + z) mod P = 0 Condition 7 indicates that the value of (x + y + z) is divisible by P. That is, the total number of data bits in one frame is 1.
It must be divisible by the number of modulation bits P per symbol.

If x bits, y bits, and z bits are set so as to satisfy the above conditions, even if the baud rate B, the modulation bit number P per symbol, and the frame bit number z are changed, (a) 19.2K, 16.8 K, 14.4K, 12.0K, 9.6K, and 7.2Kbp
Even if the transmission speed of the modem such as s changes, a secondary channel with a constant speed can be obtained.

(B) A constant frame signal can be obtained.

(C) Can generate 2400Hz, which is necessary for synchronization with terminals.

Rm for P, B, x, y, and z satisfying the above conditions 1 to 7
= 19.2K, 16.8K, 14.4K, 12.0K, 9.6K, 7.2K, and 4.8K
I tried for bps.

However, 19.2K P = 7, 16.8K P = 7, 14.4K P = 6, 12.0K P = 5, 9.6K P = 4, 7.2K P = 3, When 4.8K, P = 2.

Further, an error correction code is used in order to improve the characteristics of the secondary channel, but since this is a method of increasing the reliability by using the redundancy bit which is an error correction code, B, x , Y, z were selected.

As a result, an example of the case of Rs = 192 bps is shown in FIG.
Another example is shown in FIG. 1 (c).

In either case, the frame frequency is 96 Hz and is constant even if the main channel speed Rm changes, and satisfies the above (b).

Since y is always 2, a secondary channel having a constant speed is obtained, which satisfies the above (a).

Further, by taking i and j as shown in the figure, 2400 Hz can be generated, and the above (c) is satisfied.

The maximum number of bits (x + y + z) for one frame is 203.

FIG. 2 is a diagram showing an embodiment of the secondary channel system according to the present invention.

In the figure, 1, 2, 6, and 7 are buffers, 3 is a transmission control unit, 4 is a normal modem transmission unit, 5 is a timing circuit, 8 is a reception control unit, and 9 is a normal modem reception unit.

On the transmitting side, the transmission data SD of the main channel M-CH is sent to the buffer 1 and the transmission data SD of the secondary channel S-CH.
SD is input to the buffer 2 respectively.

Suppose now that the speed Rm of the main channel is 19.2K and the example shown in FIG. 1 (b) is taken.

The transmission control section 3 operates by the output of the timing circuit 5, and as shown in FIG.
A frame is created with 0 bits, 2 bits of the secondary channel data y, and 1 bit of the frame bit z, and this frame is sent to the transmitter 4 of the normal modem 96 times per second.

On the reception side, the reception control unit 8 extracts a frame signal from the signal received by the reception unit 9 of the normal modem, and the main channel data x200 bits and the secondary channel data y2 are extracted.
Separate bits and generate 2400Hz. The main channel data x200 bits are sent to the buffer 6, and the secondary channel data y2 bits are sent to the buffer 7, and are output from the buffers 6 and 7 as received data RD at a predetermined timing.

When the main channel speed Rm changes to 16.8K, the transmission controller 3 changes the main channel data x to 175 bits and the frame bit z to 5 bits, but does not change the secondary channel data y to 2 bits. Even if the main channel speed Rm changes, the frame frequency 96Hz does not change, and the secondary channel speed 192b
ps does not change either.

〔The invention's effect〕

As described in detail above, according to the present invention, (1) the secondary channel information can be transmitted by slightly increasing the used band of the main channel.

(2) It is possible to easily obtain a signal for synchronizing the baud rate on the line of the modem with the communication speed between the terminals and a frame signal necessary for synchronizing the symbols inside the modem.

(3) By varying the number of bits for the frame signal, the transmission rate of the secondary channel can be kept constant even if the transmission rate of the main channel changes.

(4) Since an error correction code is used for the secondary channel, it has a great effect such as a characteristic that the error rate is smaller than that of the main channel.

[Brief description of drawings]

FIG. 1 (a) is an explanatory view of the principle of the secondary channel according to the present invention. Both FIG. 1 (b) and FIG. 1 (c) are explanatory views. FIG. 2 is a diagram showing an embodiment of the secondary channel system according to the present invention. FIG. 3 is an explanatory diagram of a conventional secondary channel. In the figure, M-CH is a main channel, S-CH is a secondary channel, G is a guard band, 1, 2, 6, and 7 are buffers, 3 is a transmission control unit, 4 is a normal modem transmission unit, and 5 is timing. A circuit, 8 is a reception control unit, and 9 is a reception unit of a normal modem.

Claims (1)

[Claims] 1. In a multi-valued PSK type modem that uses a voice band and configures a secondary channel by a time division method, main channel data, secondary channel data using error correction code, and frame bits. In 1
When a frame is configured and the speed of the main channel changes, the number of modulation bits per symbol and the number of the frame bits are changed to keep the cycle of the frame constant and to change the speed of the secondary channel. Secondary channel system characterized by holding constant.