FR2492198A1 - Simplex digital transmission with reduced band width - has modulator and demodulator at each station with encoder controlled by recorder of same module to avoid drop in effective bit rate - Google Patents

Abstract

The system contains a modem at each end of the transmission path, e.g. a telephone line. Each modem comprises a coder which receives the data to be transmitted and a decoder which receives the transmitted data. Each modem has also a controlling device used by the decoder to control the coder of the same modem in order that the data received by the modem modify the internal state of the coder. The device is formed by a pair of switches for each modem. The switches connect the decoder output to the coder input when the modem receives a transmitted data and prevent the re-emission of the data.

Description

 The present invention relates to the bidirectional transmission of signals on the same transmission channel, such as a single telephone line, by a half-day transmission procedure, that is to say a procedure consisting in transmitting a series of information. , such as a digital information packet, at one end of the channel, receiving it at the other, then transmitting another information packet the other way, receiving it and so on. The invention relates more particularly to a digital transmission system in the half-board in which the spectral congestion is reduced, in particular by the elimination of the DC component and the reduction in the level of low frequencies, without increasing the bit rate to be transmitted.

 As is known, it is generally sought in such a system, therefore comprising an encoder-decoder module at x each end of a - transmission channel, the suppression of the continuous component of the transmitted message, in order to allow a possible remote power supply and to simplify the circuits of transmission and reception of the signals, as well as the minimization of the bandwidth normally necessary to correctly transmit the information.

 It is known, in unidirectional digital transmission, to achieve these objectives by using a limited digital sum code or limited alternated sum code, respectively, or the two sums of which are limited in the case where all of these properties are sought. It will be recalled that the numerical sum is the sum of the values of the symbols of the code used between the instant chosen as the origin of transmission and any instant, and that the alternated sum is the sum of the values of the symbols of even rank minus the sum of the odd rank symbols of the same code.

In bidirectional transmission, the coding being carried out at each end of the transmission line alternately, this solution is not applicable: there are indeed discontinuities in the evolution of the digital sums when the direction of transmission is changed , i.e. coder. Nevertheless, different solutions are known to solve this problem, among which we can cite
- the use of known transmission codes and the addition of additional elements, transmitted at the end of the packet in order to always obtain the same value of the digital sum or of the alternating sum at the end of the packet, whatever the content of this;
- the creation of new transmission codes which include only digital sum or zero alternating sum words, which of course leads to a zero sum for the entire packet. In both cases, the value of the digital sum or of the alternating sum is the same at the end of each packet, whether it is emitted by one or the other end, and the envelope of the spectrum of the electrical signal on the line is identical to the spectrum emitted by the signals digital in the case of a unidirectional transmission. The drawback of these two methods is to artificially increase the time for transmitting packets for the same transmission rate: the bit rate of useful information transmitted is therefore reduced.

 The present invention relates to a transmission system comprising an encoder-decoder module at each end. a line, which avoids these drawbacks. To this end, this system uses the same codes as in unidirectional transmission and this with the same spectral performance, thanks to the control of the coder by the decoder of each module, so that each packet received by the decoder changes the internal state of the encoder. It is recalled that the internal state of an encoder is understood to mean the state of this encoder as it is characterized by the two values of the digital sum and of the alternating sum respectively, at the end of a transmission unit (word or package).

More specifically, the system according to the invention comprises a
alternating digital transmission system, comprising
at least one transceiver module at each end of a transmission channel, each of the modules comprising
- an encoder receiving the information to be transmitted
- a decoder receiving the transmitted information
means for controlling the coder by the decoder of the same module, the information received by the module changing the internal state of the coder.

 Other objects, characteristics and results of the invention will emerge from the following description, given by way of nonlimiting example, and illustrated by the appended figure which represents an embodiment of the system according to the invention.

 The transmission system shown in the figure therefore includes a transceiver module 10 located at one end of a transmission channel 3, such as a telephone line, at the other end of which is connected another module d reception 20.

The module 10 includes an input M1 on which the messages to be transmitted are received and an output S2 where the received and decoded messages are available. The module 10 also includes an encoder C1 connected to the input M1 and supplying a transmitter E1 with a coded message corresponding to the message to be transmitted, The transmitter
E1 being itself connected to line 3. To line 3 is also connected a receiver R2 receiving a coded message and transmitting it to a decoder D2, which supplies a decoded message corresponding to the message received, on output S2 . As is known, the transmitter E1 and the receiver R2 are both connected to line 3 via a switch A12 controlled by a synchronization device S10. In addition, the output of the decoder D2 is also connected to the encoder C1 input via a switch A11, also controlled by the synchronization device
Similarly, the transceiver module 20 includes a receiver R1 connected to line 3 via a switch A22, receiving the message sent by the module 10 and transmitting it to a decoder D1, which provides on its output S1 the message received and decoded. The module 20 also includes an encoder
C2 receiving a message M2 to be transmitted from module 20 to module 10 and supplying the same coded message to a transmitter E2, which is connected to line 3, also through the switch A22. As before, the output of the decoder D1 is connected to the input of the coder C2 via a switch
A21. The switches A21 and A22 are controlled by a synchronization device S20.

 The operation of this device is as follows.

 A message to be transmitted from module 10 to module 20 is therefore provided on input M1. The synchronization device S10 controls the switch A1 1 so that it connects the input M1 to the encoder C1 (position 1). The message is then coded in element C1, then transmitted to element E1 which transmits on line 3, the switch A12 authorizes the connection (position 1).

The synchronization device S20 of the module 20 then controls the switch A22 so that it connects line 3 with the receiver R1 (position also marked 1), which allows the reception of the message and its decoding by the element D1 which provides the decoded message on the output
Simultaneously, the device S20 controls the switch A21 so that it connects the output S1 with the encoder C2 (position always marked 1), which has the effect of changing the internal state of the encoder C2 as a function of the message received by module 20.

This is the only effect of this connection, because the switch A22 being in position 1, the transmitter E2 is not then connected to line 3.

The internal state of the C2 encoder is no longer changed at the end of the received message.

When then the module 20 receives, on its input M2, a message to be sent to the module 10, the synchronization device S20 causes the switches A21 and A22 to pass into position marked 2, that is to say that the input M2 is connected to the C2 encoder and the transmitter
E2 is connected to line 3, with the advantage that the message to be transmitted finds the coder C2 in the state in which the message received previously left it, which ensures in the same way as in a one-way transmission the boundary of digital sums.

 The message sent by the module 20 is received by the module 10 in a similar manner to the previous reception by the module 20, that is to say that the synchronization device S10 controls the setting of the switches A11 and A12 in position 2, thus ensuring the connection of line 3 with the receiver R2 and the connection of the output S2 with the encoder C1, which makes it possible to change the internal states of the encoder C1 as a function of the message received, and this only during its reception.

 The system described above therefore performs at the level of each module the control of the coder by the decoder, by means of a simple additional switch (A1 and A21 respectively). It is understood that it is possible to carry out this control of the coder by the decoder by any other known means.

 In an alternative embodiment (not shown), there is inserted into each module a device for detecting transmission errors or a device for detecting the absence of reception of coherent signals, produced by any known means, and further provided with means inhibiting the encoder of the module in which it is located, for example via the synchronization device (S10 'S20)> so that any transmission errors do not cause the internal state of the encoder to change. However, this solution is complex and is only justified in the case where a high quality of the spectrum of the transmitted signals is desired: indeed, the action of a transmission error on the encoder of the receiver module does not entail new transmission errors, but only a degradation of the spectrum due to the parasitic evolution of the internal states of the encoder.

 This system therefore ensures a practical equivalence between the spectra of signals in half-cycle and one-way transmission, without increasing the bit rate to be transmitted and by using the same coders and decoders in both cases.

Claims (3)

 1. Alternating digital transmission system, comprising at least one transmission-reception module (10, 20) at each end of a transmission channel (3), each of these modules comprising  - an encoder (C1, C2) receiving the information to be transmitted  - a decoder (D1, D2) receiving the transmitted information; the system being characterized by the fact that each of the modules also comprises means for controlling the coder by the decoder of the same module, so that the information received by the module changes the internal state of the coder.  2. System according to claim 1, characterized in that the control means comprise a referral system (Al1, A21, A12, A22) connecting the decoder output (D1, D2) to the encoder input (C1, C2) when the module (10, 20) receives transmitted information, and inhibiting the re-transmission of the latter .  3. System according to claim 1, characterized in that each of the modules (10, 20) further comprises a device for detecting transmission errors or the absence of received signals, comprising means for inhibiting the encoder (C1 , C2) of the module (10, 20) in which it is located, so that the detection of a transmission error does not change the internal state of the encoder (C1, C2).