FR2511568A1 - Amplitude regulator for optical fibre TV transmission system - uses difference between synchronising and black level signals to control gain of input stage amplifier - Google Patents

Abstract

The video signal output from a demultiplexer unit is applied to a sync. signal reconstitution generator and to sync. and black level selectors. Monostables in series in the sync. level circuit have time constants of greater than the half line and full line timer periods resp. The second monostable output gates the video signal for application to a capacitance memory. Monostables in series in the black level circuit each have time constants of less than the black level time period. The second monostable gates the video signal to apply the black level pulse for each line to a capacitive memory. The memory outputs are applied to a difference circuit which normalises the sync. pulse amplitude w.r.t a predetermined value from a potentiometer. This current effects control through a gain controlled amplifier at the input of the receivers.

Description

RECEIVING MODULE OF A
TRANSMISSION OF TELEVISION SIGNALS
The present invention relates generally to television signal transmission systems and relates more particularly to a receiver module used in the transmission of television signals.

 A system is already known for transmitting television signals constituted by composite video signals associated with a sound channel. In general, it comprises a transmitter module and a receiver module connected together by a line or transmission channel constituted for example by a coaxial cable. The receiver module used essentially comprises a detector of television signals transmitted over the coaxial cable, an amplifier of the detected signals, and a demultiplexer intended to reproduce the composite video signals and the sound.

 In order to restore the composite video signals with respective amplitudes equal to a normalized value of a peak-to-peak volt, the receiver module of the type described above comprises an automatic gain control circuit for the aforementioned amplifier. This control circuit consists of a so-called synchronization level detector and a so-called black level detector, thus making it possible to regulate the amplitude of the synchronization signals and the amplitude of the video signals to said normalized value.

 In addition, in order to obtain good quality television images, it is known to equip the receiver module with a circuit making it possible to align or calibrate all the detected video signals to the same predetermined value, by means of 'a diode and a capacitor.

 However, such a receiver module has drawbacks.

Indeed, the fact of aligning the video signals on the same fixed value, that is to say without slaving, leads to instability of the television image obtained. In addition, the use of a coaxial cable as a transmission line has electrical characteristics which are insufficiently efficient for the transmission of television signals.

 The object of the present invention is to remedy these drawbacks by proposing a receiver module used in the transmission of television signals, which is entirely satisfactory, and ensures both perfect regulation of the amplitude of the composite video signals and an alignment of the said signals. video signals on their respective black levels, by means of two independent control loops one from the other, thus giving rise to television images of very good quality.

 In addition, the transmission line used is advantageously an optical fiber, giving the receiver module excellent performance due to all the technical advantages inherent in optical fibers.

To this end, the subject of the invention is a receiver module of a system for transmitting television signals transmitted over a transmission channel, the television signals comprising composite video signals consisting of video signals and line and frame synchronization pulses. , the receiver module comprising means for detecting the composite video signals transmitted on the channel, and means for keeping constant the amplitude of the detected composite video signals, controlled by a control circuit, characterized in that the control circuit comprises: :
- means for restoring line and frame synchronization pulses, connected to the detection means;
- first means for selecting the so-called synchronization level corresponding to the line synchronization pulse background, connected to the output of the rendering means;
- second means for selecting the so-called black level of each video signal, connected to the output of the rendering means; and
means for differentiating between the black level and the synchronization level, thus making it possible to obtain the amplitude of each line synchronization pulse which is set to a determined value, the holding means connected to the differentiation means thus regulating the amplitude of each video signal so as to deliver a composite video signal of constant amplitude.

 According to another characteristic of the invention, the receiver module also comprises a servo circuit ensuring the alignment of the video signals on their respective black levels, said alignment being obtained by superposition of the signal corresponding to the black level of each video signal composite video signals.

Other characteristics and advantages of the invention will appear better in the detailed description which follows and which refers to the appended drawings, given solely by way of example and in which:
- Figure 1 shows a diagram of the receiver module according to the invention; and
FIG. 2 represents diagrams as a function of time of the signals present at different places in the diagram of FIG. 1.

 According to an exemplary embodiment and with reference to FIG. 1, the receiver module of a system for transmitting television signals constituted by composite video signals associated with a sound channel, firstly comprises a base 10 known as for receiving television signals transmitted over a transmission line or channel, such as for example a single mode or multimode optical fiber.

 The receiving base 10 comprises a photodetector 11, such as for example an avalanche photodiode or a PIN type semiconductor diode, optically coupled to the fiber 20, the anode of which is connected to ground via a load resistance R, and the cathode of which is connected to a supply + U.

 The photodetector 1 1 converts the light radiation received after propagation in the optical fiber 20 into an electrical signal generated at the terminal T of said photodetector.

 This electrical signal is then presented to a low noise preamplifier 12, constituted for example by a field effect transistor, and provided with an automatic gain control (AGC).

 The preamplifier 12 is followed by an equalizer system 14, of conventional structure, intended to provide a correct frequency response (bandwidth equal for example to 8 MHz) of the reception base 10.

 At the output of the equalizer 14 is connected an output amplifier 15 delivering the television signals whose amplitude is kept constant and equal to a normalized value of a peak-to-peak volt, as will be seen below.

 At the output of the receiving base 10 is connected a demultiplexer 25 intended to reproduce the composite video signals and the sound constituting the television signals transmitted over the optical fiber 20. The demultiplexer 25 comprises a bandpass filter 26 and a pass filter -bas 27, the respective inputs of which are connected together at N constituting the input of the demultiplexer 25.

 The bandpass filter 26 is followed by a frequency demodulator 28, of conventional structure, generating at its output the sound channel S. It will be noted that the frequency demodulator 28 could be replaced by an amplitude demodulator, without leaving the part of the invention.

 The low-pass filter 27 generates at its output the composite video signal Vc as represented as a function of time in the diagram a in FIG. 2.

As shown in diagram a, the video signal consists
te Vc, complying for example with the standards of the SECAM color television system, and implementing a so-called interleaved screen analysis, first comprises a set of video signals V representative of each line of the frame, for example pair as shown partly to the left of the diagram a.

The amplitude of each video signal V is between a so-called black level NN equal to 0 volts and a so-called white level Ng equal to +0.7 volts.

The composite video signal VC also includes so-called line synchronization signals S1 each consisting of a pulse of duration equal to 4.8 days, and the amplitude of which is defined between a level known as the line pulse end level, which will be taken in what follows as a reference for the black level NN (equal to 0 volts), and a level called synchronization line NS equal to -0.3 volts. So,
The amplitude of the composite video signal VC, corresponding to the amplitude of the video signals V and of the line synchronization pulses Sl, is equal to 1 volt peak to peak. As it appears on this diagram a, the duration of a line is equal to 64s and the duration of the line pulse end stop or black level NN is equal to 5.41us.

 To ensure the transition from the even frame to the odd frame, the latter not being represented, the composite video signal VC further comprises a so-called frame synchronization signal St consisting of a train of standardized pulses (SECAM system) each having an amplitude equal to that of the line synchronization pulses S1.

 The structure of the means used to ensure, on the one hand, the maintenance of the composite video signals VC at a constant amplitude of a volt peak to peak, and, on the other hand, the alignment or setting of the video signals, will be described in what follows. V on their respective black levels NN.

 Referring to FIG. 1, the receiver module comprises a generator 30 for rendering line synchronization pulses S1 and frame St, receiving the composite video signal VC generated by the demultiplexer 25.

 This generator 30, comprising for example a set of filters followed by an amplifier and a comparator (not shown), outputs a signal D restoring the line and frame synchronization pulses.

 Diagram b of FIG. 2 represents this signal D as a function of time. This consists of the line S1 and frame synchronization pulses! It, put in logic form using for example a so-called positive logic, that is to say that at a zero voltage corresponds a level "0" and that a positive or negative voltage (- + 5 volts in Figure 2) corresponds to a level "1".

 The output S 'of the generator 30 is connected to a circuit 40 making it possible to select the synchronization level N5 corresponding to the line synchronization pulse background Sl. More precisely, this circuit 40 includes a first monostable 41 whose time constant (48, il) is chosen to be greater than the duration of a half-line (32us). In addition, this monostable 41 is triggered on the rising edge of each pulse of the signal D generated by the generator 30, and is retriggered for any pulse present during the time interval (48rus) corresponding to the stable state of said monostable.

Diagram c of FIG. 2 represents, as a function of time, the signal Q1 generated by the monostable 41. This signal Q1 passes from level "0" to level "1" at each line synchronization pulse Sl, and remains at level "1" for the duration of the frame synchronization signal
The monostable 41 is followed by a second monostable 42 whose time constant (78jus) is chosen to be greater than the duration of a line (64, pus). In addition, this monostable 42 is triggered on each rising edge of the signal Q1 generated by the first monostable 41, and is retriggered for any rising edge present during the time interval (78Sus) corresponding to the stable state of said monostable 42 .

The diagram d of FIG. 2 represents as a function of time the signal Q2 generated by the monostable 42. This signal Q2 is at level "0" for substantially the entire duration of the frame synchronization signal
The circuit 40 also includes switching means, such as for example an analog gate 43, controlled by the signal Q2 generated by the monostable 42, and receiving the composite video signal Vc. Thus, when the signal Q2 has its level 0 "0" (diagram d in FIG. 2), the gate 43 is triggered and detects the level N5 of the background of the synchronization pulses.

 The output of analog gate 43 is connected to a memory 44, for example of the capacitive type, memorizing the level of the background of the synchronization pulses once detected by said gate 43.

The output S 'of the generator 30 is also connected to a circuit 50 allowing the black level NN of each line to be selected. More specifically, this circuit 50 comprises a first monostable 51 whose time constant (2jais) is chosen to be less than the duration of the level of the black NN (5.4us in diagram a of FIG. 2). In addition, this monostable 51 is triggered on the falling edge of each pulse of the signal D generated by the generator 30, and outputs a signal taken from its terminal Q'1-
The diagram e in FIG. 2 represents, as a function of time, the signal Q'1 generated by the monostable 51. This signal Q'1 is constituted by a train of pulses having a level "0" at each falling edge of the pulses of lineS1 and frame synchronization
The monostable 51 is connected to a second monostable 52 having a first input connected to the Q'1 output of the monostable 51 and a second reset input (RESET) connected to the Q2 output of the monostable 42. This monostable 52 has a constant identical in time to that of monostable 51 (2Sus in the example- chosen), and is triggered on the falling edge of the pulses of signal Q'1.

The diagram f of FIG. 2 represents as a function of time the output signal Q'2 of the monostable 52. This signal Q'2 comprises pulses corresponding to the black level NN of each line, and remains at level "0" (state blocked from monostable 52) for substantially the entire duration of the frame synchronization signal
The circuit 50 also includes switching means, such as for example an analog gate 53, controlled by the signal Q'2 generated by the monostable 52, and receiving the composite video signal Vc for which the black levels NN can vary from one line to another. Thus, during each pulse of the signal Q'2 (diagram f in FIG. 2) corresponding to the level of the black, the gate 53 is triggered and detects the level of the black NN of each line.

 The output of the analog gate 53 is connected to a memory 54, for example of the capacitive type, memorizing each level of black once detected by said gate 53.

 We will now explain how the composite video signals are maintained on the one hand at a constant amplitude (I volt peak to peak) and on the other hand the alignment of the video signals on the black level.

 As it appears in FIG. 1, there is shown at 60 a differentiator, of conventional structure, connected at the output of the two memories 44 and 54, and making the difference between the signal corresponding to the levels NS of the synchronization pulse funds detected and then memorized, and the signal corresponding to the levels of black NN detected and then memorized. The differentiator 60 therefore restores at its output the amplitude of the line synchronization pulses S1 which is adjusted to the normalized value of -0.3 volts by means for example of a potentiometer (not shown).

The differentiator 60 is followed by a low-pass filter 62 connected to the AGC terminal of the preamplifier 12. Thus, once the amplitude of the line synchronization pulses set to said normalized value (-0.3 volts), the regulation of the amplitude of each video signal V to the normalized value of +0.7 volt by implementing the automatic gain control (AGC) of the preamplifier 12 by varying the transconductance of the field effect transistor
establishing said preamplifier. Consequently, the composite video signal generated by the amplifier 15 has a constant amplitude normalized to 1 volt peak to peak.

70 has been shown in Figure 1 a summator, conventional structure, performing the superposition of the signal corresponding to the black levels NN detected and then stored, the composite video signal Vc. Thus, the adder 70 restores the low-frequency components of each video signal and aligns or shifts the video signals V at the black level NN. The video signals V thus aligned are then filtered by a low-pass filter 72 so as to
restore a good quality video image.

Of course, the invention is in no way limited to the mode of
realization described and represented and includes all equivalents
techniques of the means described as well as their combinations if those
these are carried out according to the spirit of the invention and implemented
in the context of the claims which follow.

Claims (12)

 1. Receiver module of a television signal transmission system transmitted over a transmission channel (20), the television signals comprising composite video signals (VC) consisting of video signals (V) and line synchronization pulses (ground) and frame (St), the receiver module comprising means (11) for detecting the composite video signals transmitted on the channel, and means (12) for keeping constant the amplitude of the detected composite video signals, controlled by a control circuit, characterized in that the control circuit comprises:  - means (30) for restoring line (S1) and frame (St) synchronization pulses, connected to the detection means (11);  - first means (40) for selecting the so-called synchronization level (Ns) corresponding to the line synchronization pulse background, connected to the output of the restitution means (30);  - second means (50) for selecting the so-called black level (NN) of each video signal, connected to the output of the reproduction means; and  - means (60) for differentiating between the black level and the synchronization level, thus making it possible to obtain the amplitude of each line synchronization pulse (S1) which is adjusted to a determined value, the holding means (12 ) connected to the differentiation means thus regulating the amplitude of each video signal (V) so as to deliver a composite video signal (VC) of constant amplitude.  2. Receiver module according to claim 1, characterized in that the first selection means (40) comprise first (41) and second (42) monostable connected in series, and first switching means (43) receiving the video signals detected and being controlled by the signal generated by the second monostable, these switching means detecting the synchronization level (nu).  3. receiver module according to claim 2, characterized in that the first monostable (41) has a time constant greater than the duration of a half-line and in that the second monostable (42) has a greater time constant the duration of a line.  4. Receiver module according to one of claims 1 to 3, characterized in that the synchronization level (Ns) is selected for substantially the entire duration of the frame synchronization pulse  5. Receiver module according to one of the preceding claims, characterized in that the second selection means (50) comprise third (51) and fourth (52) monostable connected in series, the fourth monostable (52) having an input of reset connected to the output of the second monostable (42), and second switching means (53) receiving the detected video signals and being controlled by the signal generated by the fourth monostable, these switching means detecting the black level ( NN) of each video signal.  6. Receiver module according to claim 5, characterized in that the third (51) and fourth (52) monostable each have a time constant less than the duration of the black level of the video signals.  7. Receiver module according to one of the preceding claims, characterized in that it further comprises first means (44) for memorizing the synchronization level generated by the first selection means (40), and second means (54 ) for memorizing the level of black generated by the second selection means (50), the respective outputs of the first and second memorization means being connected to the differentiation means (60).  8. Receiver module according to one of the preceding claims, characterized in that it also comprises means for aligning each video signal on the black level (NN).  9. Receiver module according to claim 8, characterized in that the alignment means comprise the aforementioned restitution means (30), the aforementioned second selection means (50), the aforementioned second storage means (54), and means (70) for superimposing the signal corresponding to the black level of each video signal to the composite video signals (VC), thereby delivering the video signals (V) aligned with the black level (NN).  10. Receiver module according to one of the preceding claims, characterized in that the means for maintaining constant the amplitude of the detected composite video signals comprise amplification means (12) having an automatic gain control input connected to the output differentiation means (60).  11. Receiver module according to one of the preceding claims, characterized in that the composite video signals (VC) transmitted on the transmission channel (20) are associated with a sound signal (S), and in that the module comprises means (25) for demultiplexing the composite video signals and the sound, having an input connected to the detection means and two outputs connected to the video channel (VC) and to the sound channel (S), respectively.  12. Receiver module according to claim 11, characterized in that the demultiplexing means (25) comprise a bandpass filter (26) whose output is connected to the sound channel, and a low pass filter (27) whose output is connected to the restitution means (30), the respective inputs of the two filters being connected to each other, thus constituting the input (N) - of the demultiplexing means.  13. Receiver module according to one of claims 11 and 12, characterized in that the output of the demultiplexing means connected to the sound channel (S) is connected to a frequency demodulator (28).  14. Receiver module according to one of the preceding claims, characterized in that the transmission channel (20) is free optical and in that the detection means comprise a photodetector (11) disposed opposite the optical fiber.