SU815969A1 - Stereo colour reproducing device - Google Patents

Description

(54) STEREO-COLOR PLAYING PRODUCT

Claims (1)

The invention relates to television and can be used in broadcast and applied television to reproduce a stereo color television (TV) image transmitted by a single lens stereo color television camera. A stereo color reproducing device is known comprising a decoding unit, the first and second outputs of color difference signals of which are connected to respective inputs of the matrix, and the first, second and third outputs of the matrix are connected respectively through amplifiers of green, blue and red color difference signals with corresponding modulating inputs of color signals kinescope, to the cathode of which the output of a broadband luminous signal amplifier is connected, anaglyph glasses placed in front of the screen color kinescope 1. However, the known device has poor-quality color reproduction of the observed stereo color image. The purpose of the invention is to improve the color reproduction of the observed stereo color image. The goal is achieved by the fact that in a stereo color reproducing device containing a decoding unit, the first and second outputs of the color difference signals of which are connected to the corresponding inputs of the matrix, and the first, second and third outputs of the matrix are connected, respectively, through the amplifiers of green, blue and red color difference signals with corresponding modulating inputs of chrominance signals of a color kinescope, to the cathode of which is connected, the output of the amplifier of a broadband luminous signal, anaglyph glasses, have In front of the color kinescope screen, one of the filters in anaglyph glasses contains a consistent spectral characteristic of the red and green phosphors of the color kinescope, and the spectral characteristic of the other filter is matched with the blue and green phosphors of the color kinescope, in addition, a line delay line has been introduced, low pass filter and high pass filter, combinational amplifier, type of work switch, leveling delay line, electronic switch, adder, subtractive the unit, the first and second detectors, while the output of the left and right stereo channels transmitted through the string of signals is connected to interconnected inputs of a high-pass filter and a switch of work, the first output of which is connected via a low-pass filter to interconnected first and second inputs of electronic the switch and the input of the delay line to the line, the output of which through the compensating amplifier is connected to the third and fourth inputs of the electronic switch, the control input of which is connected output color synchronization block decoding, the first output of the electronic switch is connected simultaneously with the first inputs of the subtracting unit and the adder, and the second output of the electronic switch is connected to the second inputs of the subtractive unit and the adder, and the third input of the adder is connected via an equalizing delay line to the output of the high-pass filter and the second output is a switch of the type of work, while the output of the adder is connected to the input of the amplifier of a broadband luminous signal, and the output of the subtractive unit is With the control input of the amplifier of the green color-difference signal directly, with the control input of the amplifier of the blue color-difference signal through the first detector, and with the control input of the amplifier of the red color-difference signal through the second detector. FIG. 1 shows the structural electrical circuit of the proposed device; in fig. 2 - diagrams explaining his work; in fig. 3 - spectral transmission characteristics of anaglyph glasses for the proposed stereo color reproducing device (CCTV). The device comprises a decoding unit 1, a matrix 2, amplifiers 3-5 of green, blue and red color difference signals, a kinescope 6, an amplifier 7 of a wideband luminance signal, a delay line 8 for a line, a low filter 9 and a high-pass filter 10, a compensating amplifier 11, a switch 12 types of work, equalizing delay line 13, electronic switch 14, adder 15, subtractive unit 16, first 17 and second 18 detectors. The device works as follows. When installing the switch 12, the type of work in the left position according to the scheme, the luminance signals of the left and right stereo channels alternating with the line frequency (Fig. 2a and b), go through the low-pass filter 9 to the electronic switch 14 and to the delay line 8 per line. Compensating amplifier 11 equalizes the amplitude of the signal in the forward and delayed channels. Thus, when the electronic switch 14 is in the first position. its outputs contain the currently transmitted loudspeaker signal of the left stereo channel and the signal of the right stereo channel delayed by the line. When the electronic switch 14 is in the second position, its outputs contain a delayed line signal of the left stereo channel, which was transmitted during the previous line, and a currently transmitted time signal of the right stereo channel. As a result, loudspeaker signals of the left and right stereo channels are formed at both outputs of the electronic switch 14. However, the signals formed at the outputs of the electronic switch 14 (Fig. 2 in c to d) are lined with high-frequency components, since the signals before switching in the electronic switch 14 and delay pass through the filter 9 of low frequencies. The high-frequency components (Fig. 2 (5) through the high-frequency filter 10 and the equalizing delay line 13 go to the adder 15, which also receives signals from both outputs of the electronic switch 14. At the output of the adder 15, a luminous signal is formed (Fig. 2e), corresponding to the sum of the luminance signals of the right and left stereo channels, i.e., the fully open aperture of the lens. The luminance signals of the left and right stereo channels from the output of the electronic switch-14 also go to both inputs of the subtracting unit 16, which generates a paral- lel signal xa (Fig. 2g), equal to the difference between the luminance signals of the right and left stereo channels. The parallax signal is bipolar (Fig. 2g), this is explained by the fact that the parallax value has both positive and negative values. The parallax signal through the detector 18 acts to the control input of the amplifier 5 of the red color difference signal, through the detector 17 to the control input of the amplifier 4 of the blue color difference signal, and directly to the control input of the amplifier 3 of the green color difference signal. As a result, a positive spike in the parallax signal locks the red and green spotlights of the color kinescope 6, and the negative burst blocks the blue and green spotlights. The color difference signals of red, blue and green are shown respectively in diagrams 3, s and k (Fig. 2). The transfer object in this example is a white object on a black background, so if the parallax signal affected the control inputs of amplifiers 3-5, then the color difference signals would be zero. As a result of matrixing, the chromaticity of red, green and blue signals are formed in the kinescope 6 (Fig. 2n, m to n). The luminance signal reproduced on the color kinescope and perceived by the observer with the left eye is shown in the diagram of the signal o (Fig. 2), with the right eye in the diagram of the signal n (Fig. 2). The spectral characteristics of anaglyph glasses for observing such an image are shown in FIG. 3 a. Since the green color of the parallax edging is not transmitted, the spectral characteristics of the anaglyph glasses provide transmission of the light flux from the green phosphor of the kinescope 6 to both eyes of the observer. FIG. 36 shows the appearance of a defocused image of a white object against a black background in the CCTV mode of operation, which provides for the reproduction of color parallax edging and watching a stereo color television (TV) image, the blue edging is indicated by the letter C and is marked with vertical hatching, the red border is indicated by the letter K and is marked with oblique hatching. FIG. Sv shows the waveforms of the chrominance signals corresponding to such an image (Fig. 2 l, m and n). Normal color TV transmission in this case is reproduced in the usual way, i.e. as it would be reproduced on the screen of a standard color TV receiver. When installing switch 12 to the right position according to the scheme, in filters 9 and 10, compensating amplifier 11, electronic switch 14, delay line 8, subtraction unit 16, and there is no signal on detectors 17 and 18. The adder 15 passes the signal from the equalizing line 13 of the delay without changing the amplifier signal 7 to the amplifier 7, the control inputs of the amplifiers 3-5 of the color difference signals do not receive a parallax signal and they work as ordinary amplifiers of the color difference signals in a standard color TV receiver, which plays the role of CCTV when installing switch 12 to the right in the scheme position. Normal color TV transmission in this case is reproduced in the usual way, as on a standard color receiver, and when playing on the screen of a kinescope 6 CCTV video signals from a stereo color TV camera, the image on the screen of a kinescope looks the same as in a standard color TV receiver. Invention Stereo-color reproducing device containing a decoding unit, the first and second outputs of color difference signals of which are connected to the corresponding inputs of the matrix, and the first, second and third outputs of the matrix are connected respectively via amplifiers of green, blue and red color difference signals with corresponding modulating inputs of color signals color kinescope, to the cathode of which the output of the amplifier of a broadband luminous signal is connected, anaglyph glasses that can be placed A screen of a color kinescope, characterized in that, in order to improve color reproduction of the observed stereo color image, one of the filters in anaglyph glasses contains a consistent spectral characteristic of the red and green phosphors of the color kinescope, and the spectral characteristic of the other filter is matched with the blue and green phosphors of the color kinescope. In addition, a delay line per line, a low-pass filter and a high-pass filter, a compensating amplifier, are included. work type detector, equalization delay line, electronic switch, adder, subtraction unit, first and second detectors, the output of the left and right stereo channels transmitted through the line of the speaker signals to interconnected high-pass filter inputs and the type of switch, the first output of which connected through a low-pass filter to the interconnected first and second inputs of the electronic switch and the input of the delay line per line, the output of which is connected via a compensating amplifier to the third and fourth inputs of the electronic switch, the control input of which is connected to the color synchronization output of the decoding unit, the first output of the electronic switch is connected simultaneously to the first inputs of the subtractive unit and the adder, and the second output of the electronic switch is connected to the second inputs of the subtracting unit and an emator and the third input of the adder is connected via an equalizing delay line to the output of the high-pass filter and the second output of the switch of the type of work, while the output of the adder is Inonii broadband amplifier with input luminance signal, and the output of the subtractor unit is coupled to a control input of the amplifier green chrominance signal directly to the control input of the amplifier blue color difference signal - via a first detector and a control input of the red color difference signal amplifier through the second detector. Sources of information taken into account in the examination 1. US Patent No. 3712199, cl. G 03 B 35/08, 1973 (prototype). 1 a 5 5 g d Xi 1g m and one I i ".m. -Jliu / J to J Uc "E Fmg.Z