RU2037977C1 - Stereochrominance tv signal transceiver - Google Patents

Abstract

FIELD: television engineering. SUBSTANCE: stereochrominance TV signal transceiver has on sending end two stereoscopic television cameras, two cross-bar converter, two switches, two low-frequency filters, color picture signal shaper, comb filter, band filter, rejection filter, amplitude modulator, adder; on receiving end it has rejection filter, tuning delay line, comb filter, first delay line, switch, two frequency detector units, two cross-bar converters, two delay lines, three-channel commutator, three frequency changer units, three frequency detector units. EFFECT: improved compatibility of device with SECAM. 4 dwg

Description

 The invention relates to television technology, namely to stereoscopic color television systems, and can be used in stereo broadcast color television systems, as well as in applied special television systems.

 A device for transmitting and receiving a stereo-color television signal comprising a first matrix signal converter, the two outputs of which are connected respectively to the first and second inputs of the switch, the output of which is connected to the first input of the second matrix signal converter, the second input of which is connected to the output of the first matrix converter signals and with the input of the first low-pass filter, the output of which is connected to the first input of the first balanced modulator, the second input of which ohm is connected to the output of the subcarrier frequency generator, and the output is with the first adder input, the second low-pass filter, the input of which is connected to the output of the second matrix signal converter, and the output is with the first input of the second balanced modulator, the second input of which is connected through the phase-shifting circuit to the output of the subcarrier generator frequency, and the output with the second input of the adder, the third matrix signal converter, connected in series with the delay line and with the third input of the adder, and in series on the receiving side connected by a notch filter and a delay line, a band-pass filter whose output is connected to the synchronizing input of the subcarrier frequency generator, the first input of the first synchronous detector through a delay line for a duration of one line duration, with the first input of the second synchronous detector and with the first input of the third synchronous detector, the second the inputs of the first and second synchronous detectors are combined and connected to the output of the subcarrier frequency generator through a phase-shifting circuit, a switch, the first input of which is connected with the output of the first synchronous detector, and the second input with the output of the second synchronous detector, a matrix signal converter, the first two inputs of which are connected respectively to the first and second outputs of the switch, and the third with the output of the third synchronous detector, the second input of which is connected to the subcarrier frequency generator.

 This device provides compatibility with color television systems.

 However, it provides only partial compatibility (by brightness signal), and full compatibility is not provided with any of the standard color television systems. Also, the device transmits in color only one frame of a stereo pair.

 This is because the subcarrier frequency signal is quadrature modulated by the luminance narrowband signal of the right frame of the stereo pair and the color difference narrowband signals of the right frame of the stereo pair through the line. For the left frame of a stereo pair, only a luminance signal is generated.

 The closest in technical essence to the proposed one is a device for transmitting and receiving a stereo-color television signal, which contains on the transmitting side the first stereo-television color transmitting camera, the outputs of which are connected to the corresponding inputs of the first matrix signal converter, the first output of which is connected to the first input of the subtraction unit and to the first the adder input, the second input of which is connected to the output of the amplitude modulator, the input of which is connected to the output of the second lower filter x frequency, the first low-pass filter, the input of which is connected to the output of a controlled two-input switch, the first and second inputs of which are connected respectively to the second and third outputs of the first matrix signal converter, a frequency modulator, the input of which is connected to the output of the first low-pass filter, and the output from the third input of the adder, the second stereo television color transmitting camera, the outputs of which are connected to the corresponding inputs of the second matrix signal converter, the output of which is connected with the second input of the subtraction unit, the output of which is connected to the input of the second low-pass filter. On the receiving side, this device contains a notch filter, the output of which is connected to the input of the trim delay line, the output of which is connected to the first input of the matrix signal converter, the other two inputs of which are connected to the outputs of the first and second blocks of frequency detectors, respectively, the input of each of which is connected to the corresponding the output of a two-channel switch, the first input of which is connected to the output of the first delay line for a time duration of one line, the input of which is connected to the second input vuhkanalogo switch and with the output of the first band-pass filter, a second delay line for a duration of one line, the output of which is connected to the first input of the subtraction unit, the second input of which is connected to the input of the second delay line for a duration of one line and with the output of the frequency conversion unit, the input of which connected to the output of the second band-pass filter, the input of which is connected to the inputs of the first band-pass filter, a notch filter and a low-pass filter, the output of which is connected to the second input of the adder, the output of which is connected to the output of the amplitude detector, the input of which is connected to the output of the subtraction unit 23.

 The disadvantage is the poor quality of compatibility with the SECAM color television system.

This drawback is due to the fact that the spectrum of the auxiliary subcarrier frequency modulated in amplitude by the difference signal U _(Yп-Yл) is located in the range of 1-3 MHz of the spectrum of the luminance broadband video signal of the left side of the stereo pair, which is compatible for ordinary monoscopic black-and-white and color television receivers. This makes interference from the auxiliary subcarrier visible on monoscopic black and white and color TV screens. The second reason for the poor quality of compatibility is the presence of a continuous spectrum of the subcarrier frequency, frequency-modulated by the color difference signals of the left frame of the stereo pair, in the spectrum of the luminance broadband video signal of the left frame of the stereo pair. This makes the interference from this subcarrier noticeable on monoscopic black and white television screens.

 The aim of the invention is to improve the quality of compatibility of the device for transmitting and receiving stereo-color television signal with the SECAM color television system.

 This is achieved by the fact that in the device for transmitting and receiving a stereo-color television signal containing on the transmitting side the first stereo-television color transmitting camera, the outputs of which are connected to the corresponding inputs of the first matrix signal converter, the first output of which is connected to the first input of the adder, the second input of which is connected to the output amplitude modulator, the first input of which is connected to the output of the second low-pass filter, the first low-pass filter, the input of which is connected to the output of a dual input switch, the first and second inputs of which are connected respectively to the second and third outputs of the first matrix signal converter, the second stereo television color transmitting camera, the outputs of which are connected to the corresponding inputs of the second matrix signal converter, and on the receiving side a notch filter, the output of which is connected to the input tuning delay line, the output of which is connected to the first input of the matrix signal converter, the other two inputs of which are connected the outputs of the first and second blocks of frequency detectors, respectively, the input of each of which is connected to the corresponding output of the two-channel switch, the first input of which is connected to the output of the first delay line for a duration of one line, the input of which is connected to the second input of the two-channel switch, the second delay line for the duration of one line, the first frequency conversion unit, the first amplitude detector, on the transmitting side a controlled three-input switch is introduced, the inputs of which are connected s with the corresponding outputs of the second matrix signal converter, and the output with the input of the second low-pass filter, a notch filter, the output of which is connected to the third input of the adder, a band-pass filter, the output of which is connected to the second input of the amplitude modulator, a comb filter, the output of which is connected to the input of the notch filter and an input of a band-pass filter, an SECAM color signal former, whose output is connected to the input of the comb filter, and the input to the output of the first low-pass filter, and at the receiving This is a comb filter, the input of which is connected to the input of the notch filter, and the output with the input of the first delay line for a duration of one line and with the second input of a two-channel switch, a delay line for a time of two lines, the input of which is connected to the output of the comb filter and with the input of the second a delay line for a time duration of one line, a controlled three-channel switch, the first input of which is connected to the output of the delay line for a time duration of two lines, the second input with the output of the second delay line and the time of the duration of one row, and the third input with the output of the comb filter, with the input of the first delay line for the duration of the duration of one line and with the second input of the two-input switch, the second and third frequency conversion blocks, the inputs of which are connected to the corresponding outputs of the controlled three-channel switch, the first output which is connected to the input of the first frequency conversion unit, the second and third amplitude detectors, the inputs of which are connected to the outputs of the corresponding frequency conversion units, and the input the first- amplitude detector connected to the output of the first frequency conversion section, and a second matrix converter signal, whose inputs are connected to outputs of the respective amplitude detectors.

 The stereo-color television signal transmission device comprises a first stereo-television color transmitting camera 1, the outputs of which are connected to the corresponding inputs of the first matrix signal converter 2, the second and third outputs of which are connected to the first and second inputs of the controlled two-input switch 3, connected in series with the first low-pass filter 4 and with the SECAM color shaper 5, the output of which is connected to the input of the comb filter 6, the output of which is connected to the input of the bandpass filter 7 and the input of the notch filter 8, the adder 9, the third input of which is connected to the output of the notch filter 8, and the first input with the first output of the first matrix signal transducer 2, the second stereo television color transmitting camera 10, the outputs of which are connected to the corresponding inputs of the second matrix a signal converter 11, the outputs of which are connected to the corresponding inputs of a controlled three-input switch 12 connected in series with a second low-pass filter 13, the output of which th is connected to the first input of the amplitude modulator 14, a second input coupled to an output of the bandpass filter 7, and an output to a second input of the adder 9.

In the SECAM color television system, a color subcarrier modulated in frequency with color signals is located in the spectrum of the luminance signal. Moreover, its spectrum is continuous. This device proposes the spectrum of a subcarrier frequency signal modulated by color signals to be transmitted not continuous but discrete in order to place it in the relatively free intervals of the luminance signal spectrum, and then it is proposed that this spectrum-discrete signal of a frequency modulated subcarrier be modulated in amplitude by right-handed signals frame of a stereo pair, for example, by luminance signals of cyan, yellow and magenta, in turn in rows. In the SECAM color television system, a frequency-modeled color subcarrier signal is subjected to high-frequency pre-emphasis. These pre-emphasis pursues a twofold goal: to reduce the visibility of the subcarrier on the image details of achromatic and low saturated colors, as well as to increase noise immunity. In fact, the frequency-modulated subcarrier signal after high-frequency pre-emphasis becomes artificially modulated and in amplitude with a modulation depth (within the nominal deviation Δ f _nomR 280 kHz and Δ f _nomB 230 kHz) to m 66% (for the color subcarrier signal during D transmission _R 'for red with 100% saturation).

 In this case, the minimum amplitude of the color subcarrier cannot be less than 160 mV, and the maximum not more than 476 mV. Experiments with an analogue showed that one frame of a stereo pair can be transmitted with reduced clarity (in a narrow frequency band), while the clarity of a three-dimensional image is estimated subjectively by the best frame of a stereo pair, i.e. volume information is transmitted for large and medium-sized parts, for which color information is transmitted in all color television broadcasting systems.

In this device, instead of high-frequency pre-emphasis introduced on the transmitting side of the SECAM color television system, it is proposed to introduce its amplitude modulation by additional narrow-band signals of the stereo frame’s right frame. At the same time, in order to preserve the goal of high-frequency predistortions introduced in the SECAM system, it is necessary to select such a group of modulating signals, the transmission of which would weaken the visibility of the subcarrier on black-and-white and low-saturated image details. The brightness signals of the left U _Yl and right U _Yp frames of the stereo pair are strongly correlated with each other, since they relate to the same image with a small offset. Consequently, an increase in U _Yl, increases, and U _Yn and vice versa. The strongest interference from the subcarrier frequency on the screens of black-and-white TVs will be visible on the bright details of the image, which, in accordance with the general pattern for real non-self-luminous objects, usually have minimal saturation. To reduce the noticeability of the interference from the subcarrier on the screens of black and white TVs when transmitting bright image details, the amplitude of the subcarrier should be minimal, i.e. above 160 mV. This condition is satisfied by the negative amplitude modulation of the subcarrier frequency by unipolar signals of the right frame of the stereo pair U _{(Y-0.3R) p} , U _{(Y-0.11B) p} and U _{(Y-0.59G) p} . The greater U _Yl , i.e. the brighter the image, the greater U _Yp , the greater U _{(Y-0.3R) p} , U _{(Y-0.11B) p} and U _{(Y-0.59G) p} and, therefore, the smaller the signal of the subcarrier amplitude modulated signals U _{(Y-0.3R) p} , U _{(Y-0.11B) p} and U _{(Y-0.59G) p} . Experiments with an analogue showed that the signals of the second frame of the stereo pair can be transmitted with a compression coefficient of K 0.2 relative to the luminance signal of the left frame of the stereo pair U _Yl , provided that the noise immunity and minimum visibility of the interference from the subcarrier are displayed on the screens of black and white TVs. In our case, this means that we select the modulation depth based on this condition, i.e. not 66% as discussed above, but 20% In addition, a shorter modulation depth will facilitate the operation of amplitude limiters that face frequency discriminators in conventional color receivers of the SECAM system and cut off spurious amplitude modulation.

The maximum value of the signal U _{(Y-0.3R) p is} obtained at R _p 1 and Y _p 1 and is equal to 0.7 V, the maximum value of the signal U _{(Y-0.11 R) p} at B _p = 1 and Y _p 1 is 0.89 V and the maximum value of the signal U _{(Y-0.59G) p} at G _p 1 and Y _p 1 is 0.41 V. To equalize the dynamic range of the signals U _{(Y-0.3R) p} , U _{(Y- 0.11B) p} and U _{(Y-0.59G) p, we} choose the following compression ratios: K _R 1, K _B 0.78, K _G 1.7, i.e. we adjust the dynamic range of the signal U _{(Y-0.11B) p} , narrowing it, and the signal U _{(Y-0.59G) p} , expanding it to the dynamic range of the signal U _{(Y-0.3R) p} . The choice of signals U _{(Y-0.3R) p} , U _{(Y-0.11B) p} and U _{(Y-0.59G) p} allows us to achieve the smallest difference in the size of the subcarrier in adjacent rows and, thus, get rid of the effect of "blinds " This is due to the fact that in each of these signals there is a component Y _p with a weight coefficient of 1.

This device proposes to sample the spectrum of the subcarrier frequency signal frequency-modulated by the color signals of the left frame of the stereo pair in order to place it in the relatively free intervals of the luminance signal spectrum of the left frame of the stereo pair U _Yл . Firstly, this allows to improve the compatibility of this device with a black-and-white television system, i.e. makes the interference from the subcarrier frequency less noticeable on black-and-white and color TV screens. Secondly, this allows you to filter the signal of the subcarrier frequency from the luminance signal of the left frame of the stereo pair U _Yl and thus increase the noise immunity of both the color channel of the left frame of the stereo pair and the channel of the right frame of the stereo pair. The discretization is performed in such a way that only the “allowed” frequencies are possible in the spectrum of the subcarrier frequency modulated by the color signals of the left frame of the stereo pair, i.e. frequencies f _p (2n + 1) f _p / 2, where n is an integer.

In addition, in order for the frequency discriminators of the receivers of the SECAM system to transmit zero values when transmitting achromatic image details, it is proposed to introduce two “forbidden” frequencies f _OR and f _OB , the values of which correspond to the values accepted in the SECAM system, in the sampled spectrum wherein the transmission of the two 'forbidden' to implement the phase rotation frequencies for the subcarrier ¹⁸⁰ in, SECAM system adopted in accordance with the law in order to reduce the visibility of the black and white television subcarrier on screens etc. and transfer of achromatic details. When transmitting the "allowed" frequencies, the phase rotation of the subcarrier by 180 ^{° is} not performed.

 A device for transmitting a stereo color television signal (see figure 1) works as follows.

Color-separated video signals from the first (left) stereo-television transmitting camera 1, corrected by gamma correctors, are fed to the first matrix signal converter 2, where the signals U _Rl ^{1 / γ} , U _Gl ^{1 / γ} and U _Bl ^{1 / γ are} converted into the brightness signal of the left frame stereo pairs U _Yl , which is supplied to the first input of the adder 9, and the color difference signals of the left frame of the stereo pair D _Rl 'and D _Bl ' are the same as in the SECAM color television system. Signals D _Rl 'and D _Bl ' arrive respectively at the first and second inputs of a controlled two-input switch 3, which is controlled by line-frequency switching pulses. It switches the line-by-line signal D _Rl 'and the signal D _Bl ', which then go to the first low-pass filter 4, where their spectrum is limited to 1.5 MHz. Further, these signals are fed to the input of the SECAM 5 chroma signal generator. The functions of the SECAM 5 chroma signal generator are to frequency modulate the subcarrier with signals D _Rl and D _Bl 'sequentially through the line, as well as to sample the spectrum of the frequency-modulated subcarrier so that in the spectrum only “allowed” frequencies were present, as well as two “forbidden” frequencies f _OR and f _OB , the same as in the SECAM system, whose phase changes by 180 ^° at the beginning of every third line and each field.

Thus, the SECAM color signal driver 5 contains (see FIG. 2): a low-frequency predistortion block 5.1, an amplitude limiter 5.2, an analog-to-digital converter 5.3, a color code encoder 5.4, a color code decoder 5.5, a frequency synthesizer 5.6, a first switching unit 5.7 phase 0/180 ^о , the second block 5.8 switching phase 0/180 ^о , controlled multi-input switch 5.9.

 The SECAM color signal generator 5 operates as follows.

At the input of the device receives signals D _Rl 'and D _Bl ' sequentially through the line. In the low-frequency predistortion block 5.1, these signals undergo low-frequency predistortions, which serve to increase noise immunity, as in the SECAM color television system. After low-frequency predistortions, the emissions of these signals are limited in the amplitude limiter 5.2, the limiting levels of which are the same as in the SECAM central heating system. An analog signal of this sequence is fed to an analog-to-digital converter 5.3, from which the color code using the color code encoder 5.4 is transferred to the closest of the allowed combinations to the input of the color code 5.5 decoder, which generates control switching signals depending on the input color code. The control switching signals control the switches that are part of the controlled multi-input switch 5.9. Frequency synthesizer 5.6 produces “allowed” frequencies from f ₁ to f _n within the maximum subcarrier frequency deviation accepted for the SECAM color television system (+ Δf _max + 350 kHz, Δf _max 506 kHz for signal D _Rл 'relative to f _OR and + Δf _max + 506 kHz, Δf _max 350 kHz for signal D _Bl 'relative, as well as two “forbidden” frequencies f _OR and f _OB . “Allowed” frequencies go directly to the inputs of the controlled multi-input switch 5.9, and “forbidden” frequencies through blocks 5.7 and 5.8 switching phase 0/180 ^about , which change the phase frequency f _OR and f _OB at the beginning every third line and each field to reduce the noticeability of interference from the subcarriers of frequencies f _OR and f _OB on the screens of black-and-white TVs, as in the CT SECAM system.The output of the controlled multi-input switch 5.9 is the output of the driver 5 of the color signal SECAM. The controlled multi-input switch 5.9 works so that at a certain point in time, only one of the frequencies produced by the frequency synthesizer 5.6 can be switched, namely, one of the “allowed” frequencies is switched, the value of which coincides or is closest to the true value of the frequency that would be produced by the frequency modulator of a conventional SECAM color television system.

From the output of the SECAM chroma signal generator 5 (see FIG. 1), the sampled spectrum of the subcarrier frequency is fed to the input of the comb filter 6. The comb filter 6 passes only the “allowed” frequencies in the band from 1.5 MHz to + 1.5 MHz relative to the average frequency f _o 4.286 kHz, as well as the “forbidden” frequencies f _OR and f _OB . The expansion of the spectrum from 1.5 to + 1.5 MHz occurs due to the high-speed switching of frequencies generated in the frequency synthesizer 5.6, in a controlled multi-input switch 5.98 (see figure 2). From the output of the comb filter 6, this signal through the notch filter 8 is fed to the third input of the adder 9 and to the input of the bandpass filter 7. The notch filter 8 cuts out from the spectrum of the subcarrier frequency the frequency band produced by the frequency synthesizer 5.6 (see figure 2). Thus, the third input of the adder 9 receives the sampled spectrum of the subcarrier frequency from 1.5 MHz to f ₁ and from f _n to + 1.5 MHz (relative to f _o ). These high-frequency components of the subcarrier spectrum are necessary to maintain acceptable clarity of the color difference signals D _Rl 'and D _Bl ', as in the conventional _{CEKAM DT} system. In the band-pass filter 7, only the sampled frequencies generated by the frequency synthesizer 5.6 (see FIG. 2) are extracted from the entire subcarrier spectrum, which are then subjected to amplitude modulation in the amplitude modulator 14.

The color-separated video signals from the right (second) stereo television color transmitting camera 10 are fed to the second matrix signal converter 11, where the signals U _Rп ^{1 / γ} U _Гп ^{1 / γ} and U _Bп ^{1 / γ are} converted into signals U _{(Y-0,3R) p} , U _{(Y-0.11B) p} and U _{(Y-0.59G) p} with compression ratios K _R 1, K _B 0.78 and K _G 1.7. Then these signals are fed to the corresponding inputs of the controlled three-input switch 12, where they are switched sequentially line by line to the input of the second low-pass filter 13, in which their spectrum is limited to 1.2 MHz. Further, these signals are fed to the first input of the amplitude modulator 14, the second input of which receives the subcarrier frequency signal from the band-pass filter 7. In the amplitude modulator 14, the amplitude _submodule is amplitude modulated by the signals U _{(Y-0.3R) p} , U _{(Y-0, 11B) p} and U _{(Y-0.59G) p} sequentially line by line. Since the modulating signals have a spectrum of 1.2 MHz, and the nominal change in the modulated subcarrier is 280 kHz (or 230 kHz), the full spectrum of the amplitude-modulated signal at the output of the amplitude modulator 14 will not go beyond ± 1.5 MHz (relative to f _o )

This is important to prevent frequency distortion that may occur at the receiving end if this condition is not met. From the output of the amplitude modulator 14, the amplitude-modulated subcarrier signal is fed to the second input of the adder 9, the output of which produces a total video signal U _{Σ the} spectrum of which is shown in FIG. 3.

 The proposed device on the receiving side contains (see Fig. 4) a notch filter 15, a tuning delay line 16, a comb filter 17, a first delay line 18 for a duration of one line; two-channel switch 19, the first block of the frequency detector 20, the second block 21 of the frequency detector, the first matrix signal converter 22, the delay line 23 for a duration of two lines, the second delay line 24 for a duration of one line, a controlled three-channel switch 25, the first block 26 of the conversion frequency, second frequency conversion unit 27, third frequency conversion unit 28, first amplitude detector 29, second amplitude detector 30, third amplitude detector 31, second sig matrix converter 32 als.

 The proposed device for receiving a stereo-color television signal contains a notch filter 15, the output of which is connected to the input of the trim delay line 16, the output of which is connected to the first input of the first matrix signal converter 22, the other two inputs of which are connected to the outputs of the first 20 and second 21 blocks of frequency detectors, respectively, the input of each of which is connected to the corresponding output of the two-channel switch 19, the first input of which is connected to the output of the first delay line 18 for a duration one line, and the second input with its input, with the output of comb filter 17 and with the inputs of the delay line 23 for a duration of two lines, the second delay line 24 for a duration of one line, and also with the third input of a controlled three-channel switch 25, the first two inputs which is connected to the output of the delay line 23 for a time duration of two lines and to the output of the second delay line 24 for a time duration of one line, respectively, the first 26, second 27 and third 28 frequency conversion blocks, the inputs of which are connected to conductive three-channel output controls the switch 25, and outputs to the inputs of respective blocks of frequency detectors 29, 30, 31, whose outputs are connected to corresponding inputs of the second matrix converter signal 32, and inputs the notch 15 and the comb filter 17 are combined.

 A device for receiving a stereo color television signal (see figure 4) works as follows.

The resulting full stereo-color video signal U _Σ formed on the transmitting side, the spectrum of which is shown in figure 3, is supplied in parallel to the inputs of the notch 15 and comb 17 filters. The notch filter 15 provides the notion of the spectrum of the subcarrier frequency from the spectrum of the broadband luminance video signal of the left frame of the stereo pair U _Yl to reduce the noticeability of interference from the subcarrier frequency on the screen of the television receiver. Then, from the output of the notch filter 15, the luminance video signal U _Yl is input to the _trim delay line 16, where it is delayed by the delay of the color signals in blocks 17 through 32. From the output of the _trim delay line 16, the signal U _{Yl is} supplied to the first input of the first matrix signal converter 22.

From the full video signal U _Σ comb filter 17 passes only the "allowed" frequencies in the band from 1.5 to + 1.5 MHz (relative to f _o ), as well as the "forbidden" frequencies f _OR and f _OB . This increases the noise immunity of the color channel of the left frame of the stereo pair and the channel of the right frame of the stereo pair, since the signal has no interference from the signal U _Yл . Next, the subcarrier frequency signal is fed to the first input of the two-channel switch 19 through the first delay line 18 for a duration of one line, and directly to the second input. In the two-channel switch 19, line-by-line switching of direct and delayed subcarrier frequency signals occurs. The switch is switched using line frequency pulses. Phasing of the two-channel switch 19 is carried out so that the input of the first block of the frequency detector 20 comes line by line, then direct, then the delayed signal of the subcarrier frequency, frequency modulated by the signal D _Rl '. At the input of the second block of the frequency detector 21, a delayed or a direct signal of a subcarrier frequency modulated by a signal D _Bl 'is received line by line. The structure of each of the blocks of frequency detectors at their inputs includes amplitude limiters that remove the "spurious" amplitude modulation.

At the outputs of the blocks of frequency detectors 20, 21, we obtain signals U _{(RY) l} and U _{(BY) l,} respectively, which then enter the second and third inputs of the first matrix signal converter 22, respectively, where the signals U _Yl , U _{(RY) l} are converted and U _{(BY) l} into the color-separated signals of the left frame of the stereo pair U _Rl ^{1 / γ} U _Bl ^{1 / γ} and U _Gl ^{1 / γ}
The signal of "allowed" and two "forbidden" frequencies, modulated in amplitude by the signals U _{(Y-0.3R) p} , U _{(Y-0.11B) p} , U _{(Y-0.59G) p} line by line, from the output of the comb filter 17 arrives at the inputs of a controlled three-channel switch 25. Moreover, it enters the first input through the delay line 23 for a duration of two lines, the second through the second delay line 24 for a duration of one line, and directly to the third. In a managed three-channel switch 25, line-by-line switching of a direct delayed for a duration of one line duration and delayed for a duration of two lines of subcarrier frequency signals occurs. The managed three-channel switch 25 is switched using line frequency pulses. Phasing of the controlled three-channel switch 25 is carried out in such a way that the input of the first frequency conversion unit 26 comes line by line, either direct, delayed by one line, or delayed by two lines for a frequency subcarrier signal, modulated in amplitude by the signal U _{(Y-0.3R ) p} . Similarly, on the second 27 and third 28 frequency conversion blocks, subcarrier frequency signals arrive, modulated in amplitude by the signals U _{(Y-0.59G) p} and U _{(Y-0.11B) p,} respectively.

Thus, the signals of the right-hand frame of a stereo pair are averaged at the receiving side for three adjacent lines and, therefore, vertical clarity is reduced by three times. But since horizontal clarity is already reduced by reducing the frequency band, this will not lead to visual degradation of the image. The frequency conversion blocks 26, 27, 28 are identical and serve to transfer the subcarrier frequency signal to the higher frequency region to prevent distortion in the subsequent amplitude detection of signals in amplitude detectors 29, 30, 31, which emit signals U _{(Y-0.3R) p} , U _{(Y-0.59G) p} and U _{(Y-0.11B) p} . Then these signals are fed to the corresponding inputs of the second matrix signal transducer 32, where the signals U _{(Y-0.3R) p} , U _{(Y-0.59G) p} and U _{(Y-0.11B) p are converted} into the color-separated signals of the right stereopair frames U _Rl ^{1 / γ} , U _Gl ^{1 / γ} and U _Bl ^{1 / γ} .

 An example of a specific implementation of the proposed device. When executing the SECAM color shaper 5, some of its nodes, such as a low-frequency predistortion block 5.1, an amplitude limiter 5.2, an analog-to-digital converter 5.3, phase 5.7 and 5.8 switching blocks are known. The color code encoder 5.4 is a combinational type logic circuit and can be based on read-only memory (for example, on K155REZ microcircuits); a color code decoder 5.5 may be performed based on K155ID8 decoders; managed multi-input switch 5.9, managed three-input switch 12 and managed three-channel switch 25 can be constructed on the basis of a managed two-input switch; as a band-pass filter 7, you can use the Butterworth filter, as a delay line for a duration of two lines 23 you can use two delay lines ULZ-64-4; the second matrix signal converter 32 can be built on the basis of operational amplifiers K544UD2.

Thus, the developed device allows to achieve advantages in comparison with the prototype. Due to the sampling of the spectrum of the color subcarrier frequency, the amplitude modulation of this discretized color subcarrier by the narrow-band signals of the right frame of the stereo pair U _{(Y-0.3R) p} , U _{(Y-0.11B) p} and U _{(Y-0.59G) p} sequentially for three adjacent lines, compressing these signals with respect to the broadband luminance signal of the left frame of the stereo pair U _Yl improves the compatibility of the device with the SECAM color television system by reducing interference from the subcarrier frequency.

 Thus, the developed device for transmitting and receiving a stereo-color television signal has a positive effect and can be used in broadcast stereo-color television systems, as well as in systems of applied special television.

Claims (1)

 A STEREO-COLOR TELEVISION SIGNAL TRANSMISSION AND RECEIVER, comprising on the transmitting side a first color stereo television transmitting camera, the outputs of which are connected to the corresponding inputs of the first matrix signal converter, the first output of which is connected to the first input of the adder, the second input of which is connected to the output of the amplitude modulator, the first input of which is connected to the output of the second low-pass filter, the first low-pass filter, the input of which is connected to the output of a controlled two-input a switch, the first and second inputs of which are connected respectively to the second and third outputs of the first matrix signal converter, a second stereo television color transmitting camera, the outputs of which are connected to the corresponding inputs of the second matrix signal converter, and on the receiving side a notch filter, the output of which is connected to the input by the trim line delays, the output of which is connected to the first input of the first matrix signal converter, the other two inputs of which are connected to the outputs of o and the second blocks of frequency detectors, respectively, the input of each of which is connected to the corresponding output of the two-channel switch, the first input of which is connected to the output of the first delay line for a duration of one line, the input of which is connected to the second input of the two-channel switch, the second delay line for the duration of one lines, the first frequency conversion unit, the first amplitude detector, characterized in that, in order to improve the quality of compatibility with the SECAM color television system by to reduce interference from the subcarrier frequency, a controlled three-input switch is introduced on the transmitting side, the inputs of which are connected to the corresponding outputs of the second matrix signal converter, and the output is connected to the input of the second low-pass filter, a notch filter, the output of which is connected to the first input of the adder, a band-pass filter, the output of which connected to the second input of the amplitude modulator, a comb filter, the output of which is connected to the inputs of the notch and bandpass filters, the SECAM color signal driver, the output of which is connected to the input of the comb filter, and the input to the output of the first low-pass filter, and on the receiving side a comb filter, the input of which is connected to the input of the notch filter, and the output with the input of the first delay line for a duration of one line and with the second input of the two-channel switch , a delay line for a time duration of two lines, the input of which is connected to the output of the comb filter and with the input of a second delay line for a time duration of one line, a controlled three-channel switch, the first input It is connected to the output of the delay line for a duration of two lines, the second input with the output of the second delay line for a duration of one line, and the third input with the output of a comb filter, with the input of the first delay line for a duration of one line and with the second input of the two-input switch, the second and third frequency conversion units, the inputs of which are connected to the corresponding outputs of a controlled three-channel switch, the first output of which is connected to the input of the first frequency conversion unit, the second and t third amplitude detectors, the inputs of which are connected to the outputs of the respective frequency conversion units, and the input of the first amplitude detector is connected to the output of the first frequency conversion unit, as well as a second matrix signal converter, the inputs of which are connected to the outputs of the corresponding amplitude detectors.

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