WO1993001684A1 - Video system for generating or processing a video signal representing a moving picture and related data, particularly a moving picture with a soundtrack - Google Patents

Abstract

A method and a device for inserting a related data signal, particularly an audio signal, into a video signal. The related data signal is compressed and converted into compressed portions, and the compression ratio is adjusted so that each portion which initially corresponds to the length of one video signal frame has the same length as one video signal line (or a fraction of a line, or a small number of lines) once it has been compressed. Each of the portions thereby compressed is inserted into each video signal frame to replace one line (or a fraction of a line or a small number of lines). An enriched video signal representing a moving picture with related data is thereby obtained. This signal has exactly the same features as a standard video signal and may be recorded or transmitted using conventional equipment. Reverse processing (sampling of compressed audio portions followed by decompression) restores a video signal and a related data signal which are directly usable.

Description

 VIDEO SYSTEM FOR GENERATING OR PROCESSING A VIDEO SIGNAL REPRESENTATIVE OF A MOBILE IMAGE AND ASSOCIATED INFORMATION, IN PARTICULAR A SOUND MOBILE IMAGE

The invention relates to a video system for the insertion of at least one signal representing information (said associated information signal) into a video signal representative of a moving image in order to obtain a video signal, said signal. enriched video, and / or to provide reverse processing of the enriched video signal obtained in order to extract the video signal and at least one directly exploitable associated information signal. The invention applies in particular to insert at least one audio signal (associated information signal) in order to obtain an enriched video signal (designated in this case video signal o / audi o), representative of a moving image in which the sound is synchronized with the image.

Traditionally, in conventional video techniques, the audio channel (s) are recorded on the video tapes by means of special heads, which requires specific equipment and limits the number of possible audio channels (generally to three). When the video signal is transmitted over the air, the audio channels require specific subcarriers with the appropriate processing, which results in congestion of television frequencies.

Furthermore, methods are known which consist in inserting an audio channel into a video signal in order to deliver sound comments in correspondence with a still image. In particular, the patent FR 2,651,629 describes a method in which a compression of the audio signal corresponding to the comments is carried out, the compressed signal then being inserted into an entire frame of the video signal to constitute a frame, called pseudo- frame. image, interspersed among the other frames. In use, this frame is decompressed and stored to then deliver the sound in correspondence with the still image. However, this technique which has the advantage of being able to be implemented in the absence of special audio heads or subcarriers specific audio in case of transmission, is limited to the production of video images which are fixed for a certain duration; moreover, it only allows one audio channel to be inserted into the video signal.

Other patents describe processes having a similar purpose (adding comments on a fixed image); for example in US Pat. No. 4,647,985, provision is made to store the sound information in a special memory; a signal inserted in the video signal triggers the reading of this memory. This technique requires significant storage means and has the same limits as the previous technique.

Furthermore, other patents describe systems using audio signal compression to ^" insert it into a video signal or record it on video disc (FR-A-2.505.593, EP-A-0.429.358, US 3,789,137,

US 4,266,243). These systems generally do not allow the insertion of several audio channels to be carried out and, in any case, do not provide any flexibility for carrying out this insertion at locations chosen according to the application, which can be easily modified, and for reproducing the desired channel. In addition, no system is capable of carrying out both direct and reverse processing with simple means.

The present invention proposes to improve existing systems; it relates in particular to a device for inserting into a video signal at least one signal of associated information, which makes it possible to obtain an enriched video signal (for example representative of a moving sound image) without having to modify the materials existing (television, video recorder, camcorder).

The insertion device targeted by the invention comprises, in combination, a video input EV, at least one associated information input EA, a separator SEP of synchronization signals s _y , s-- connected to the video input, an analog / digital converter CAN receiving the associated information signal, an MDA memory connected to the analog / digital converter CAN, a digital / analog converter DAC connected to the output of said memory MDA, a MIX mixer connected to the EV video input and to the digital / analog converter DAC and adapted to deliver the enriched video signal to an SVA output, a PLL phase-locked loop connected to the SEP splitter to receive the synchronization signals s _y , s _n and adapted to deliver, on the one hand, ra read addresses to the memory MDA, on the other hand, a control signal s ₂ at the read frequency F ₂ to the digital / analog converter DAC, a PLC MP connected to the SEP separator to receive the synchronization signals s _y , s ^ and programmed to deliver a control signal s., at the write frequency Fi to the analog / digital converter CAN, write addresses wa to the MDA memory and the validation validation signal valmel, on the one hand, to the said MDA memory in order to trigger the reading, on the other hand, to the MIX mixer to control the switching of the latter, and a selector of SELIG lines connected to the PLC in order to deliver to the latter a selection signal l _g of the line or fraction of line chosen.

Thus, the method of the invention leads to an enriched video signal which has very exactly the same nature as an ordinary video signal and which, therefore, can be processed in the same way as a video signal with the same equipment (recording , transmission, reception). It is possible to insert into the video signal several associated information signals (for example several audio signals representative of different sounds) by assigning in each frame of the video signal a different selected line to each associated information signal.

The enriched video signal thus synthesized can be processed to extract the associated information signal (s) and make them directly usable, without modification of existing equipment, with the simple addition of a processing device comprising in combination an EVA enriched video input. , a SEP separator of synchronization signals s _y , s _h connected to the enriched video input EVA, an analog / digital converter CAN connected to the enriched video input EVA, an MDA memory connected to the analog / digital converter ADC, a digital / analog converter DAC connected to the output of said memory MDA, an associated information output SAE connected to the digital / analog converter DAC, a phase locked loop PLL connected to the separator SEP to receive the synchronization signals s _v , s- ^ and adapted to deliver, on the one hand, write addresses a 'to the memory MDA, on the other hand, a control signal s' ₂ at the write frequency F ' ₂ to the digital / analog converter DAC, a PLC MP connected to the SEP separator to receive the synchronization signals s _y , s ^ and programmed to deliver a control signal s' - at the reading frequency F' .- to the digital / analog converter DAC, read addresses ra 'to the MDA memory and the validation validation signal valext to the said MDA memory, and a SELIG line selector connected to the automaton in order to deliver to the latter a selection signal 1-, of the line or fraction of line chosen. This processing device takes in real time from each frame of the enriched video signal, the portion of the associated information signal selected and ensures a decompression over time of the portions thus sampled in order to reconstruct an associated information signal (in particular signal audio synchronized with the video signal).

It should be noted that by the expression "in each frame" is meant both the insertion in all the frames of the video signal (without exception) and the regular insertion in certain frames only (for example one frame on two, or three).

The invention extends to a mixed device capable of carrying out either the insertion or the treatment mentioned above according to the operating mode chosen by a function selection. This device comprises, in combination, video input means EV, EVA capable of receiving a video signal or an enriched video signal, at least one associated information input EA capable of receiving an associated information signal, a SEP separator synchronization signals s _y , s _h connected to the video input means EV, EVA, a SELFONC function selector adapted to deliver a signal i / e representative of the insertion / extraction operating mode, an analog / digital ADC converter, a MUX1 multiplexer connected, on the one hand, to the video input means EV, EVA and to the associated information input EA for receive the signals present at these inputs, on the other hand, to the analog / digital converter CAN to deliver towards this one of these signals according to a command signal of cdm mode, an MDA memory connected to the analog / digital converter ADC, a digital / analog converter DAC connected to the output of said MDA memory, a mixer MIX connected to the video input means EV, EVA, MUXO, a demultiplexer MUX2 connected, on the one hand to the digital / analog converter DAC to receive the signal from it, on the other hand, to the mixer MIX and to an associated information output SAE to deliver to one of these signals depending on the mode control signal cdm, a phase locked loop PLL connected to the SEP separator and adapted to deliver read addresses ra, write addresses wa ', a control signal s at the read frequency F and a control signal s' ₂ at the write frequency F' , a MUX3 multiplexer connected, on the one hand, to the PLL loop to receive the signals and addresses originating therefrom, on the other hand, to the analogical / digital ADC converter CAN, to the digital / analog converter DAC and to the memory MDA to deliver to them as a function of the mode control signal cdm, respectively the control signal s ' ₂ , the control signal s, and the read or write addresses ra, wa', a PLC MP connected SEP separator and SELFONC function selector and programmed to generate a control signal if the F.- write frequency, a control signal _S'j to the frequency of reading F'- _| , write addresses wa, read addresses ra ′, the insertion validation signal valmel, the extraction validation signal valext and the aforementioned cdm mode control signals functions of the signal i / e representative of the mode of operation, a MUX4 multiplexer connected, on the one hand, to the PLC to receive the signals coming from it, on the other hand, to the analog / digital converter CAN, to the digital / analog converter DAC and to the memory MDA to deliver to them as a function of the mode control signal cdm respectively the control signal s * -, the control signal s'-i and the write addresses wa or read ra '.

Other characteristics, objects and advantages of the invention will emerge from the description which follows with reference to the appended drawings, which show embodiments of devices in accordance with the invention and the corresponding timing diagrams. In these drawings:

FIG. 1 is a block diagram of an insertion device for obtaining a video / audio signal,

FIGS. 2a to 21 are timing diagrams illustrating the insertion process implemented in said device,

FIG. 3 is a block diagram of the microprocessor-based controller used,

FIG. 4 is a block diagram of a device for processing a video / audio signal to deliver usable video signals and audio signals,

- Figures 5a and 5b are timing diagrams illustrating the operation of the processing device of Figure 4, - Figure 6 is a block diagram of a device according to the invention, capable of performing the above insertion or processing - evoked according to the chosen mode.

The device shown by way of example in FIG. 1 is intended to insert audio signals (in the example two in number, but this number is not limited) in a video signal in order to obtain a video signal / audio representative of a moving sound image.

The video signal, a frame of which is illustrated in FIG. 2a and a line in FIG. 2b, is a standard video signal for example with 625 interlaced lines. This signal comprises a line synchronization signal s ^ composed of tops between each line and a frame synchronization signal s _v composed of tops between each frame.

This video signal is introduced into the device on an EV video input. The audio signals are introduced into the device on audio inputs EA (in the example two in number: EA--, EA ₂ ). An example of an audio signal is shown in Figure 2c.

The video signal is delivered, on the one hand, to an amplifier of the conventional AMPLIV type in order to calibrate it, on the other hand, to a SEP splitter adapted to extract the line synchronization signals s ^ and frame s _y therefrom. The audio signals are delivered to amplifiers such as AMPLIS provided on each audio channel in order to calibrate them, then to a COM switch which makes it possible, at all times, to select the audio signal to be inserted on command of an MP microprocessor controller described further.

At the output of the COM switch, the selected audio signal is delivered to an analog / digital ADC converter. This converter performs a sampling of the audio signal on command of a control signal s ^ supplied by the MP automaton. This control signal, of frequency equal to or multiple of the line synchronization frequency of the video signal, conditions the sampling frequency F -, which is therefore equal to or multiple of said line synchronization frequency. In the example, the signal s-- has a frequency equal to the line synchronization frequency and the sampling is carried out at this frequency. Each sample is digitized in binary by the CAN converter which delivers a binary signal digitized at the frequency F--. Figures 2c to 2f illustrate the operation of the converter (Figure 2d; control signal s.-; Figure 2e: sampling; Figure 2f: binarization).

The binary signal from the ADC converter is delivered to a dual access memory MDA and is loaded into this memory at a write frequency equal to the frequency F.-. The write addresses wa are supplied by the MP controller.

A digital / analog converter DAC is connected to the output of the MDA memory in order to receive the binary signals read from said MDA memory and convert them into analog signals. This reading from the digital memory MDA and the analog conversion which follows are carried out at a reading frequency F at least equal to NF-, where N is the number of lines contained in a frame of the video signal.

To this end, the automaton MP which receives the synchronization signals s and S _j - from the separator SEP performs a counting of the tops of the line synchronization signal with resetting to zero at each top of the frame synchronization signal. In addition, this PLC MP receives from a selector of lines SELIG a signal for selection l _s of the line (or fraction of line) in which the insertion is to be carried out. The PLC MP compares the line count signal and the selection signal 1_, with a view to delivering an insertion validation signal valmel to the digital memory MDA. This signal triggers the reading of said memory and the conversion of the read values which are delivered in analog form to an input of a MIX mixer.

The reading frequency F ₂ is supplied to the DAC converter by a control signal S generated by a phase locked loop PLL. This frequency Fr¬ being greater than F •• (at least equal to NF--), a temporal compression of the audio signal is thus carried out and the ligson signal coming from the DAC converter is a compressed audio signal.

The read addresses ra are supplied to the memory MDA by the phase-locked loop PLL. This PLL loop conventionally comprises a voltage controlled oscillator VCO, which delivers the control signal s (frequency F), a divider counter (COMPT) which delivers the read addresses ra and a phase comparator CPH, these means being connected as shown in Figure 1.

FIGS. 2g, 2h and 2j respectively illustrate the signal s ₂ for read control at the frequency F ₂ , the digital / analog conversion carried out at this frequency by the DAC converter, and the ligson compressed audio signal obtained. This ligson signal consists of a succession of compressed portions: each portion is representative of the audio signal over a period equal to one frame. and the duration of said portion is reduced to the duration of a line if F ₂ = NF ₁ (or of a fraction of a line if F ₂ > NF- _| ).

The MIX mixer receives on its other input the calibrated video signal from the AM ^' PLIV amplifier; it is controlled by the validation validation signal valmel to be switched at each frame at the instants corresponding to the start and end of the selected line in order to insert into said line the compressed audio signal ligson. The video / audio signal from the MIX mixer is available on an SVA output for recording or transmission.

Figures 2k and 21 illustrate on the same scale (duration of about two frames), on the one hand, the audio signal, on the other hand, the video / audio signal delivered on the SVA output of the device.

In the example shown, the memory MDA is a dual-access memory, the write and read access of which are connected, on the one hand, to the PLC MP, on the other hand, to the phase locked loop PLL . Of course, any other type of equivalent storage means can be provided, in particular a conventional memory associated with access multiplexers. In addition, the MP automaton is preferably a microprocessor automaton with a PROM read only memory, a random access memory RAM, a BVF buffer, an adaptation circuit for PIA peripherals and a unit. PAL programmed logic, as shown in Figure 3. This controller could optionally be a wired controller.

Furthermore, the device shown by way of example in FIG. 4 is intended to process the video / audio signal obtained in the device in FIG. 1, to deliver a video signal and an audio signal which can be used by conventional equipment in order to generate a moving image and the corresponding sound in synchronism with said image. In this FIG. 4, the same references have been used as those of FIG. 1 for the units having the same structures and the same functions.

The video / audio signal is fed into the processing device through an EVA video / audio input. This signal is delivered, on the one hand, to an SVE video output, on the other hand, to a SEP separator of the signals of synchronization s _y , s _h , finally to an analog / digital ADC converter. It should be noted that the presence of the compressed audio line on the video signal available at the SVE output is imperceptible during the generation of the image if one chooses one or more insertion lines off screen or on the margin of the image. 'screen.

The ADC converter samples and converts the video / audio signal to digital at a frequency F ' ₂ supplied by a control signal s' ₂ . The digital signal from the ADC converter is stored in real time in a digital memory MDA at the times provided by an extraction validation signal valext which is delivered by a PLC MP. This signal valext is generated by the automaton so as to validate the memorization of the line or lines containing the compressed audio signal.

To this end, the PLC MP receives a line selection signal l _s from a line selector SELIG and the synchronization signals s _y , s _h ; it counts the tops of the line synchronization signal with resetting to zero at each top of the frame synchronization signal. The automaton compares the line counting signal thus generated and the selection signal to deliver the valext signal. The frequency of conversion and of loading into the digital memory MDA (writing frequency F * ₂ ) is provided by the control signal s' ₂ which is generated by a phase locked loop PLL. This frequency F ′ is produced by the PLL loop from the line synchronization signal s _h so that F ′ ₂ = F ₂ (F ₂ being the reading frequency during insertion, in particular equal to NF *.) .

As before, the PLL loop includes a voltage controlled oscillator VCO, a counter-divider C0MPT and a phase comparator CPH. The control signal s' ₂ carrying the frequency F ' ₂ is delivered to the CAN converter by the oscillator VCO, while the write addresses wa' are supplied to the memory MDA by the counter-divider COMPT. A digital-to-analog DAC converter is connected to the digital memory MDA in order to receive the binary signals read from said memory and to convert them into analog logical signals. C ettelec tu reetlac onv ersion analog which follows, are e fected at a frequency of

^F '2 reading F' - _j = = F .- supplied by a control signal s' - _j

N from the MP automaton. This signal s' .- is generated by the PLC from the line synchronization signal s _h . The read addresses ra ′ are supplied to the memory MDA by the PLC MP. The signal from the DAC converter is thus a decompressed audio signal whose time scale is equal to that of the initial audio signal. It is sent to an SAE audio output for processing.

The insertion device and the processing device described above with reference to FIGS. 1 and 4, can be combined in a single device making it possible to carry out, according to the chosen mode, namely insertion to deliver a video / audio signal to starting from a video signal and one or more audio signals, ie the processing of a video / audio signal to restore a video signal and one or more usable audio signals.

Such a mixed device is shown in FIG. 6. It includes the means already described for the two aforementioned devices arranged in a similar manner, namely (the previous references have been used): video input means EV, EVA capable of receiving a video signal or a video / audio signal, at least one audio input EA capable of receiving an audio signal, a SEP separator of synchronization signals s _y , s ^ connected to the video input means EV, EVA, an analog converter / digital ADC, an MDA memory connected to the analog / digital ADC converter, a digital / analog converter DAC connected to the output of said MDA memory, a MIX mixer connected to the video input means EV, EVA, MUXO, a locking loop of PLL phase connected to the SEP separator and adapted to deliver reading addresses ra, writing addresses wa ', a control signal s at the reading frequency F and a control signal from s ' ₂ to the writing frequency F' ₂ , a PLC with microprocessor MP programmed to generate a control signal s - _j at the write frequency F--, a control signal s'-, at the read frequency F '^, write addresses wa, read addresses ra ', the insertion validation signal, the extraction validation signal, and cdm mode control signals, and a SELIG line selector connected to the PLC in order to deliver a signal to it. selection l _g of the line or fraction of line chosen.

This device is also provided with additional means which allow a selection of the chosen mode.

(insertion or extraction) and operation according to this mode.

These means comprise first of all a SELFONC function selector adapted to deliver to the PLC MP an i / e signal representative of the chosen operating mode, this signal being processed by the PLC to develop the CDM mode control signals which are delivered to various multiplexers or demultiplexers described below in order to establish through them the desired connection insertion / extraction.

A MUXO multiplexer completes the video input means EV, EVA in order to connect the amplifier AMPLIV with the input of the video signal EV in insertion mode or with the input of the video / audio signal EVA in extraction mode.

A multiplexer MUX1 is connected, on the one hand, to the aforementioned input means EV, EVA (at the output of the multiplexer MUXO), on the other hand, to the audio input EA (at the output of the amplifier AMPLIS) in order to receive the signals present at these inputs and to deliver one of these signals to the analog / digital converter CAN according to the mode control signal cdm.

A MUX2 demultiplexer is connected, on the one hand, to the digital / analog converter DAC to receive the signal from it, on the other hand, to the MIX mixer and to an SAE audio output to deliver this signal to one of them depending on the cdm mode control signal.

A MUX3 multiplexer is connected, on the one hand, to the PLL loop to receive the signals and addresses originating therefrom, on the other hand, to the analog / digital converter CAN, to the digital / analog converter DAC and to the memory MDA to deliver them as a function of the mode control signal cdm, respectively the control signal s'2 _> the control signal s _2> and the addresses for reading or write ra, wa '.

Finally, a multiplexer MUX ^' 4 is connected, on the one hand, to the automaton to receive the signals coming from the latter, on the other hand, to the analog / digital converter CAN, to the digital / analog converter DAC and to the MDA memory to deliver to them as a function of the mode control signal cdm respectively the control signal s--, the control signal s * - _| and write addresses wa or read addresses ra '.

Thus, depending on the operating mode chosen (signal i / e from the SELFONC selector conditioning the signal cdm delivered by the PLC MP), the device operates like the device represented in FIG. 1 or like the device represented in FIG. 4.

Claims

CLAIMS 1 / - Device for inserting at least one associated information signal, in particular audio signal, into a video signal, making it possible to obtain an enriched video signal, in particular video / audio signal, characterized in that it comprises, in combination, a video input (EV), at least one associated information input (EA), a separator (SEP) of synchronization signals (s _v , s _h ) connected to the video input, an analog / digital converter (ADC) receiving the associated information signal, a memory (MDA) connected to the analog / digital converter (ADC), a digital / analog converter (DAC) connected to the output of said memory (MDA), a mixer (MIX) connected to the video input (EV) and to the digital / analog converter (DAC) and adapted to deliver the enriched video signal to an output (SVA), a phase locked loop (PLL) connected to the splitter (SEP) to receive synchronization signals (s _y , s _h ) and adapted to deliver, on the one hand, read addresses (ra) to the memory (MDA), on the other hand, a control signal (s ₂ ) at the read frequency F ₂ to the digital / analog converter (DAC) ), a PLC (MP) connected to the separator (SEP) to receive the synchronization signals (s _v , s _h ) and programmed to deliver a control signal (s *,) at the write frequency F- _j to the analog / digital converter (ADC), write addresses (wa) to the memory (MDA) and the insertion validation signal (valmel), on the one hand, to said memory (MDA) in order to trigger the read, on the other hand, to the mixer (MIX) to control the switching of the latter, and a line selector (SELIG) connected to the automaton in order to deliver a selection signal (l _s ) to it of the line or fraction of line chosen.

2 / - Device for processing an enriched video signal, in particular a video / audio signal, making it possible to extract therefrom a video signal and at least one signal of associated information, directly usable, characterized in that it comprises, in combination , an enriched video input (EVA), a separator (SEP) of synchronization signals (s _v , s _h ) connected to the enriched video input (EVA), an analog / digital converter (ADC) connected to the enriched video input (EVA), a memory (MDA) connected to the analog / digital converter (ADC), a digital / analog converter (DAC) connected to the output from said memory (MDA), an associated information output (SAE) connected to the digital / analog converter (DAC), a phase locked loop (PLL) connected to the splitter (SEP) to receive the synchronization signals (s _y , S _j .) And adapted to deliver, on the one hand, write addresses (wa ') to the memory (MDA), on the other hand, a control signal (s') at the write frequency F ' ₂ to the digital / analog converter (DAC), a PLC (MP) connected to the separator (SEP) to receive the synchronization signals (s „, S) and programmed to deliver a control signal (s'- _| ) at the reading frequency F '^ to the digital / analog converter (DAC), from the reading addresses (ra') to the memory (M DA) and the extraction validation signal (valext) to said memory (MDA), and a line selector (SELIG) connected to the automaton in order to deliver a selection signal (1 ,,) to the latter of the line or fraction of line chosen.

3 / - Device capable of producing, on the one hand, the insertion of at least one associated information signal into a video signal in order to obtain an enriched video signal, in particular video / audio signal, on the other hand , the reverse processing of an enriched video signal in order to extract a video signal and at least one associated information signal, directly usable, said device being characterized in that it comprises, in combination, means for video input (EV, EVA) capable of receiving a video signal or an enriched video signal, at least one associated information input (EA) capable of receiving an associated information signal, a separator (SEP) of synchronization signals ( s _v , s _h ) connected to the video input means (EV, EVA), a function selector (SELFONC) adapted to deliver a signal (i / e) representative of the insertion / extraction operating mode, an analog / digital converter (CAN), a multiplexer (MUX1) connected, on the one hand, to the video input means (EV, EVA) and to the information input associated (EA) to receive the signals present at these inputs, on the other hand, to the analog / digital converter (ADC) to deliver towards this one of these signals according to a mode control signal (cdm), a memory (MDA) connected to the analog / digital converter (ADC), a digital / analog converter (DAC) connected to the output of said memory (MDA), a mixer (MIX) connected to the video input means (EV, EVA , MUXO), a demultiplexer (MUX2) connected, on the one hand to the digital / analog converter (DAC) to receive the signal from it, on the other hand, to the mixer (MIX) and to an information output associated (SAE) to deliver to one of these signals as a function of the mode control signal (cdm), a phase-locked loop (PLL) connected to the separator (SEP) and adapted to deliver read addresses (ra ), write addresses (wa '), a control signal (s ₂ ) at the reading frequency F ₂ and a signal command (s ' ₂ ) at the writing frequency F'_2> ^a multiplexer (MUX3) connected, on the one hand, to the loop (PLL) to receive the signals and addresses originating therefrom, on the other share, to the analog / digital converter (ADC), to the digital / analog converter (DAC) and to the memory (MDA) to deliver them according to the mode control signal (cdm), respectively the control signal (s' ₂ ), the control signal (s ₂ ), and the read or write addresses (ra, wa ¹ ), an automaton (MP) connected to the separator (SEP) and to the function selector (SELFONC) and programmed to generate a control signal (s- _j ) at the write frequency F, a control signal (s '.-) at the read frequency F' .-, write addresses (wa), read addresses (ra ¹ ), the insertion validation signal (valmel), the extraction validation signal (valext) and the above-mentioned mode control signals (functions of the signal (i / e) representative of the mode d e operation, a multiplexer (MUX4) connected, on the one hand, to the PLC to receive signals from it, on the other hand, to the analog / digital converter (ADC), to the digital / analog converter (DAC) ) and to the memory (MDA) to deliver to them as a function of the mode control signal (cdm) respectively the control signal (s--), the control signal (s' *) and the write addresses (wa ) or reading (ra ').

4 / - Device according to claim 3, characterized in that it comprises a line selector (SELIG) connected to the automaton in order to deliver thereon a selection signal (l _g ) of the line or fraction of chosen line.

5 / - Device according to one of claims 1, 2, 3 or 4, wherein the memory (MDA) is a dual-access memory whose write and read access are connected, on the one hand, to the PLC (MP), on the other hand, to the phase locked loop (PLL).

6 / - Device according to one of claims 1, 2, 3, 4 or 5, wherein the controller (MP) is a microprocessor controller with a read only memory (PROM), a random access memory (RAM ), a buffer (BVF), an adaptation circuit for peripherals (PIA) and a programmed logic unit (PAL).

7 / - Device according to one of claims 1 to 6, wherein the phase locked loop (PLL) comprises a voltage controlled oscillator (VCO), a counter-divider (COMPT) and a phase comparator (CPH) connected in a loop.