RU2448433C1 - Stereoscopic television system - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: into a stereoscopic television system comprising the first and receiving sides, the first and second channels of colour display of sound signals reproduced in upper parts of screens are introduced into a receiving side.

EFFECT: accompaniment of video frames of stereo mates with colour display of stereo sound signals perceived by a spectator via glasses of separate fields of view also as volumetrical.

20 dwg, 1 tbl

Description

The invention relates to radio communications technology and can be used for digital broadcasting.

The prototype adopted "Universal television system" [1], on the transmitting side containing two photoelectric converters / photoelectric converters /, the first generates signals of three colors of the right frame of the stereo pair and three colors of the left frame, includes six ADCs of video signals that convert analog video signals into eight-bit codes, six encoders executed identically to analog encoders [2], which compress the code stream with an ADC with a floating coefficient from 1 to 255 and with an average compression ratio of 4 per frame, code generator, two triggers, per the second and second self-propelled pulse distributors / SRI /, two ADC sound signals, a frequency synthesizer and a single-channel transmitter of radio signals, on the receiving side containing a control unit / channel selection /, a path for receiving video signal codes, a first channel for processing codes from three color signal channels, a second channel processing codes from three channels of color signals, the first and second flat-panel screens.

Both frames of the stereo pair go in parallel, the polar separation of the signals of their codes is applied. On the receiving side, the compressed video information is restored by decoders by 100%, the number of samples in the rows and on the right and left screens is doubled, the right and left frames of the stereo pair are played back in parallel, which the viewer perceives through glasses of separate fields of view. Playable video mode 1000 _lines × 1600 _counts × 25 Hz. The disadvantage of the prototype is the lack of color display of sound signals on the screens of the receiving side / music, voices /.

The purpose of the invention is to introduce color displays of sound signals on the screens of the receiving side.

The technical result is the accompaniment of video frames and color display of stereo sound signals, perceived by the viewer through the glasses of separate fields of view also surround.

The essence of the invention is that in the stereo television system containing the transmitting and receiving sides, identical first and second color channels of the audio signals on the receiving side are introduced.

The invention is illustrated by drawings, where: the transmitting side is shown in FIG. 1, the structure of the digital stream from the transmitting side is shown in FIG. 2, the code generator is shown in FIG. 3, the receiving side is shown in FIG. 4, and the spectrum of the amplitude-modulated signal is shown in FIG. 5, a bipolar amplitude detector — in FIG. 6, a code doubling unit — in FIG. 7, a frame code storage device — in FIG. 8, a register block — in FIG. .11, the channel for color displaying sound signals - in Fig. 12, the drive for sound codes - in Fig. 13, the block of sound registers - in Figs. 14, 15, the general Id matrix element and placing emitting cells therein - 16, 17 emitting cell - 18, the arrangement of the matrices in the screen - 19, the timing chart of operation of the system - in Figure 20.

The sampling rate of the codes at the output of the encoders after compression of the stream of codes with a compression ratio per frame 4 is: 20 MHz: 4 = 5 MHz. The frequency of the clock sinusoidal oscillations received at the second control input of the shaper 24 codes / 1 /, is

f _t = 5 MHz × 27 = 135 MHz.

where 5 MHz is the sampling rate of the codes at the output of the encoders,

27 - the number of bits in each summary code of three color signals R, G, B (9 _bits × 3).

, период разряда 7,4 нс

. Несущая частота передатчика принимаетсяCodes 200 ns

, discharge period 7.4 ns

. The carrier frequency of the transmitter is received.

f _n = 135 MHz × 15 = 2025 M%.

The upper side frequency f _WB = 2025 MHz + 135 MHz = 2160 MHz,

lower side frequency f _nb = 2025 MHz-135 MHz = 1890 MHz.

For transmission, the lower side frequency of 1890 MHz is used. From the transmitter 33 (Fig. 1/) two code streams are transmitted on one carrier in parallel to the right and left frames. On the receiving side (Fig. 4/), the compressed video information is restored by decoders by 100%, the number of samples in lines: doubles from 800 to 1600, the right and left frames on the first to 1000 lines are displayed on both screens, and on the lines 1001 to 1250 color image 3v1 and 3v2 sound signals.

The transmitting side contains / Fig. 1 / photoelectric converter / FEP / 1, which is a sensor of signals of three colors of the right frame R, G, B and three colors of the left frame R ₂ , G ₂ , B ₂ , and including the first lens 2 and the first FDI matrix 3 / a device with charge injection / from a three-layer CMOS sensor [3 p.832], the photosensitive side of which is located in the focal plane of the first lens 2, the optical resolution of the PZI matrix is 1600 × 1000, its first and third outputs are connected to the inputs of the preliminary amplifiers, respectively 4 , 5, 6, whose outputs are n the first and third outputs of the photomultiplier tube 1. The photomultiplier tube includes a second lens 7 and a second PZI matrix 8, the photosensitive side of which is located in the focal plane of the lens 7, the first and third outputs of the PZI matrix 8 are connected to the inputs of the preamplifiers 9, 10, 11, the outputs of which are the fourth - six outputs of the photomultiplier tube 1. The transmitting side includes from the 12th to 17th identical ADC video signals that convert the analog video signals into eight-bit codes, the ADCs 12-17 are identical to the ADCs of the analog video signal [2, p. 5 of FIG. 3], includes from 18 to 23 encoders that identical to encoders of the analogue [2 p.6 of Fig.5.3], includes a code generator 24, serially connected oscillator 25 with a stability of 10 ^-7 and a frequency synthesizer 26, the first 27 and second 28 keys, the first self-propelled distributor of 29 pulses / SRI / , the second SRI 30, performed identically [4 p.269, 274], the first ADC 31 and the second ADC 32 of the sound signal, made as the ADC of the sound signal in the analogue [5 p.5 of Fig.7]. The ADCs 31 and 32 convert 3v1 and 3v2 audio signals into 16-bit codes with a frequency of 75 kHz. SRI 29 generates a horizontal sync pulse / SSI / code of 27 units in a row, SRI 30 generates a frame sync / CSI / code of 27 units in a row. The transmitting side contains a radio signal transmitter 33 from a series-connected carrier frequency amplifier 34, an amplitude modulator 35 and an output amplifier 36. An amplitude modulator 35 of a series-connected ring modulator and a band-pass filter [6 p.234], filtering out the unnecessary upper side frequency of 2160 MHz in the amplitude spectrum -modulated carrier / Fig. 5/. The ring modulator suppresses the carrier frequency itself 2025 MHz. The lower side frequency of 1890 MHz with the video information of the stereo pair codes enters the output amplifier 36 and is radiated by the antenna. With carrier stability of 10 ^{-7, the} occupied band on the air will be ± 189 Hz / or 378 Hz /. Shaper 24 codes of three channels / 3 /, the first and second channels are identical. The first includes series-connected the first block of 37 AND elements from 27 AND elements, the first 38 and second 39 OR elements, the first output key 40 and the first SRI 41, the second channel includes the second block of 42 AND elements from 27 AND elements, the third 43 and fourth 44 elements OR, the second output key 45 and the second SRI 46. The third channel includes two blocks 47 and 50 of AND elements, each of sixteen AND elements / by the number of bits in the code /, the fifth OR element 48 and the sixth OR element 51, the third SRI 49 and the fourth SRI 52. The code generator 24 includes a first 53, a second 54, and a third 55 key and eight-bit pulse counter 56 and decoder 57 connected in series. The information inputs of block 24 are: the first are the first / from 1 to 27 / inputs of the AND elements of block 37, the second are the first inputs of the AND elements of block 42, the third are the first / from 1 to 16 / inputs of AND elements of block 47, fourth — first inputs of AND elements of block 50, fifth — signal input of the third key 55, sixth — third input of the fourth OR element 44. The first output of block 24 is the combined outputs of the output keys 40, 45, the second is the third output decoder 57 connected to the input of the SRI 29. Control The inputs are: the first - combined inputs / 5 MHz / keys 53, 54 and the counting input of the counter 56 pulses, the second - combined signal inputs / 135 MHz / output keys 40, 45, the third - the control input 25 MHz / U ₀ / counter 56 pulses, the fourth is the control input 25 Hz of the third key 55. The first output of the decoder 57 is connected to the first control / U _from / the input of the key 53, the second output is connected to the second control / U ₃ / input of the key 53 and to the first control input of the second key 54, and is the second output of block 24. The second inputs of the elements AND block 37 and b OKA 42 blocks 47 and 50 are connected to the outputs of the SRI 41, 46, respectively, having 27 outputs, and the SRI 49, 52, also having 27 outputs, but only 16 outputs are connected to the second inputs of the AND elements of blocks 47, 50, the rest of the outputs are not are used. The output of the first key 53 is connected to the inputs of the SRI 41, 46, the output of the key 54 is connected to the inputs of the SRI 49, 52. The output of the third key 55 is connected to the third input of the second OR element 39. The receiving side contains / Fig. 4/ antenna, control unit 58 / channel selection /, one channel for receiving and processing video signal codes, a channel for generating control signals, first and second flat-panel screens, two channels for reproducing sound and two channels for color displaying audio signals. The path for receiving and processing codes of video signals receives codes for video signals and includes a series-connected block 59 for receiving radio signals, an amplifier 60 of a radio frequency and a bipolar amplitude detector 61 (Fig. 6/), the first and second channels for processing codes of video signals, the First channel for processing codes of video signals includes a series of connected first pulse shaper 62, the input of which is connected to the first output of the bipolar amplitude detector 61, the first receiving register 63 of 27 bits and three color signal channels Fishing: signal channel R, signal channel G, signal channel B.

R channel signal comprises a serially coupled register 64, the decoder 65, the block 66 doubling codes, drive frame 67 and unit 68 codes the pulse amplifier comprising a number of pulse amplifiers 67 drive the frame codes and outputs the code bits of 12.8 × 10 ^6/1600 × 1000 × 8 /, the signal channel G includes a series-connected register 69, a decoder 70, a block of doubling codes 71, a drive 72 of frame codes and a block 73 of pulse amplifiers from 12.8 × 10 ⁶ pulse amplifiers, the signal channel B includes a register 74, a decoder 75 , block 76 doubling codes, drive 77 codes frame and bl approx. 78 out of 12.8 × 10 ⁶ pulse amplifiers. The outputs of blocks 68, 73, 78 are connected to the corresponding 38.4 × 10 ⁶ / 12.8 · 10 ⁶ × 3 / inputs of the first flat panel screen 79. The second channel for processing video signal codes includes a second pulse shaper 80 connected in series, the input of which is connected to the second the output of the bipolar amplitude detector 61, the second receiving register 81 of 27 bits and three channels of color signals: a signal channel R ₂ , a signal channel G ₂ , a signal channel B ₂ . The signal channel R ₂ contains a register 82, a decoder 83, a code doubling unit 84, a frame code storage unit 85, and a pulse amplifier unit 86 of 12.8 × 10 ⁶ pulse amplifiers.

The signal channel G ₂ consists of a register 87, a decoder 88, a block 89 for doubling codes, a drive 90 for frame codes and a block 91 of pulse amplifiers / 12.8 × 10 ⁶ /, a signal channel B ₂ from series-connected registers 92, decoder 93, block 94 Doubling codes, drive 95 frame codes and block 96 pulse amplifiers. The outputs of blocks 86, 91, 96 are connected to the corresponding 38.4 × 10 ⁶ inputs of the second screen 97. The operating side of the receiving side determines the channel for generating control signals, including a sequentially connected block 98 for selecting horizontal sync pulses / SSI / and a frequency synthesizer 99, as well as a key 100, a counter 101 pulses and a decoder 102, and a block 103 for allocating frame sync pulses / CSI /. The receiving side includes, as in the prototype, identical first 104 and second 105 sound reproduction channels, each of which includes a converter of 16-bit codes of sound into analog signals / DAC /, power amplifier and loudspeaker Gr ₁ / Gr ₂ /. The receiving side includes the first 106 and second 107 channels of color display of audio signals. Images of the right and left frames of a stereo pair are reproduced synchronously on screens 79 / right frame / and 97 / left frame / on lines one through 1000. In the same screens, color lines of audio signals: music, voices are displayed on lines 1001 to 1250. The viewer of the image from both screens and the color image of the music perceives surround with the help of glasses 108 / Fig. 4/. Glasses 108 represent a frame with earbands, the windows of the glasses do not have glasses, are interconnected by a movable vertical axis to rotate them relative to each other in the horizontal plane, to separate the fields of view of the eyes, each window of the glasses has a conical lens hood at the end of a rectangular shape for the shape of the screens. Two-part hood: the first part is screwed into the glasses window, the second part is movable, it is pushed in and out in the first to change the length of the hood. To view the program, the viewer is located at the usual distance from both screens and in the middle between them, by turning the glasses windows horizontally and extending the hood, adjusts the resolution of the eye fields so that the left eye sees the left screen, the right sees the right screen As a result, the image from the screens The color display of sound signals at the top of the screens is also perceived volumetric. Decoders 65, 70, 75, 83, 88, 93 are identical and executed exactly like decoders in analogue [2 p.16, f.10], the process is the same. The doubling blocks of codes 66, 71, 76, 84, 89, 94 are identical, each includes / Fig. 7/ trigger 109, the input of which is the control input of the / 20 MHz / block, the first 110 and second 111 key blocks are eight in each, the first 112, second 113, third 114, fourth 115 registers, adder 116, fifth 117 and sixth 118 registers and sixteen diodes. The information inputs of the block are the bitwise combined inputs of blocks 110, 111; they are received in parallel from the decoder 65 / Fig. 4/ signal codes R with a frequency of 20 MHz. The outputs are the bitwise combined outputs 0-7 of the adder 116 and the outputs of the first to eighth registers 117, 118, which store codes for 50 ns. Frequency of repetition of codes from doubling units 40 MHz, after 25 ns. The work of the blocks for doubling codes is described in detail in the prototype [1 p.21-22 Fig.7]. Drives 67, 72, 77, 85, 90, 95 frame codes (Fig. 4/) are identical, each includes / Fig. 8/ blocks 119 _1-1000 registers according to the number of lines in the frame, of which 1000 are displayed for video frames. The information input of block 67 is the bitwise integrated first - eighth inputs of blocks 119 _1-1000 registers. The control inputs are: the first is the first 25 Hz control input of the first block 119 ₁ , the second is the combined second control inputs U _o / 25 kHz / register blocks, the third is the combined third control U _d / 40 MHz / inputs of 119 _1-1000 register blocks. Each control output of the previous block of registers is the first control input for each subsequent block of registers, the control output of the last block 119 ₁₀₀₀ registers is connected in parallel to the fourth control inputs of all blocks of 119 registers / Fig.8/. Outputs the frame code storage are parallel outputs of registers 119 of all the blocks, total yields 12.8 × 10 ^6/1600 × 8 × 1000 /. Blocks 119 registers are identical, each includes / 9, 10 / first 120 and second 121 keys, a pulse distributor 122 and eight registers 123 _1-8 , each of 1600 bits, according to the number of samples in the lad. The information inputs of block 119 registers are the first to eighth bit-wise combined third inputs of the bits of eight registers 123, the outputs are the parallel outputs of all bits / 1600 / eight registers, total outputs 12800/1600 × 8 /. The outputs of 1000 register blocks are the outputs in each drive code, which 12.8 × 10 ⁶ . The control inputs are: the first is the first control input U _from 25 Hz of the first key 120, the second is the signal input U _output / 25 kHz / second key 121, the third is the signal input U _d 40 MHz of the first key 120, the fourth is the first control input of the second key 121. The last output of the pulse distributor 122/1600 / is the control output of block 119 ₁ in the next block of registers and is connected to its first control input of the first key 120. The output of the first key 120 is connected to the input of the pulse distributor 122, the outputs of which are sequentially from the first to 1600- th p dklyucheny to the first / clock / input eight bits parallel output register 123. The second switch 121 is connected in parallel to the second inputs of the eight bits of register 123 and to the second control input ₃ of its key U 121, U extending one pulse _vyd closes switch 121. The outputs of accumulators 67, 72, 77, 85, 90. 95 frame codes / Fig. 4/ are connected to the information inputs of their blocks, respectively 68, 73, 78, 86, 91, 96 pulse amplifiers, each of which includes pulse amplifiers in terms of the number of frame resolutions and the number of bits in the code / 1600 × 1000 × 8 /, total impulse litels in the block 12.8 × 10 ⁶ . With the end of the 40 ms frame period, in the drives 67, 72, 77, 85, 90, 95 frame codes all codes of both frames of the stereo pair are concentrated, with the arrival of the signal from the last block of 119 ₁₀₀₀ registers / Fig. 8/ all frame codes are issued in parallel and synchronously in blocks of pulse amplifiers 68, 73, 78, 86, 91, 96, from the outputs of which the signals of code units, amplified and lasting 40 ms, are fed to the corresponding inputs of their screens 79, 97.

The operation of blocks 98, 103.

Block 98 allocation of lowercase SSI and block 103 allocation of CSI are identical, each includes / 11 / five-digit counter 124 pulses, decoder 125, element HE 126 and two diodes D1, D2. Counter 124 counts twenty-seven pulses in a row / code 11011 /. The information input of block 98/103 / is the counting input of the counter 124 connected to the output of the pulse shaper 62, the control input is the input of the diode D1 connected to the output of the second pulse shaper 80/4 /. In block 103, the information input is connected to the output of the second pulse shaper 80, and the control input is connected to the output of block 62. The decoder 125 output is the output of block 98/103 / and is connected to the output of the element HE 126 through the diode D2, together they are connected to the control input of the counter 124 after the diode D1. The SSI code is 27-bit of one unit, and is sent to the counting input of block 98 from the pulse shaper 62. The CSI code is also of 27 units and enters the counting input of block 103 from the pulse shaper 80. With the arrival of the SSI / SSI / code to the counter input of the counter 124, it counts 27 pulses in a row: at the outputs 1, 2, 4, 5 of the digits, signals appear which are decoded by block 125, and the SSI line clock goes from the output of block 98. At the moment of receipt of the SSI code at the input of the counter 124, there are no pulses from the output of block 80. Beginning with the second code of the line, from block 80 the codes will go to the control input of counter 124, and with the arrival of each pulse of the code, counter 124 will be reset and will not be able to reach count 27. In parallel, codes from block 62, in which there are ones and zeros: for each zero, the element NOT 126 gives out a pulse that resets the counter 124; in addition, when the SSI pulse comes out from block 125, it goes through the diode D2 to the control input of the counter 124 and also resets it. Thus, the circuit blocks 98, 103 exclude the appearance of false signals SSI, CSI at the output. The operation of block 103 is similar to the operation of block 98. When PEC 1 / Fig. 1/ operates, the FDI matrix 3 generates three analog video signals of the right frame of the stereo pair R, G, B, the FDI matrix 8 forms three analog video signals of the left frame R ₂ , G ₂ , V ₂ . The work of the matrices is identical. Lens 2 creates an image on the photosensitive side of the array of FDI 3, each of the three layers of which from the key 27 receives pulses of 25 kHz line frequencies to read the signals of the pixels of the matrix vertically, the second input of the matrix from the key 28 receives pulses of 20 MHz to read the signals of pixels along lines [3 p.832]. The analog video signals R, G, B from the FDI 3 are fed to the inputs of the preliminary amplifiers 4-6, the outputs of which are fed to the inputs of the ADC 12-14, from their outputs are fed to the inputs of the encoders 18-20. A similar path are the video signals R ₂ , G ₂ , In ₂ and fed to the inputs of the encoders 21-23. The synchronization of reading signals from the pixels of the FIR sensors 3, 8 is performed by the leading edge of the pulse of 25 Hz, which opens the keys 27, 28. The frequency synthesizer 26 produces: 25 Hz frame frequencies from the first output, 5 MHz pulses from the second output to the control inputs of encoders 18-23 and to the first control input of block 24, from the third output pulses of 75 kHz sampling sound codes, from the fourth - sinusoidal clock oscillations of 135 MHz to the second control input of block 24, from the fifth - pulses of 25 kHz line frequencies to the signal input of key 27, the third control input Lok 24 and the third control inputs of the ADC 31, 32, the sixth output pulses of 20 MHz sampling ADC codes 12-17 and the signal input of the key 28, the seventh output sinusoidal oscillations of the carrier frequency of 2025 MHz with a stability of 10 ^-7 to 33 radio transmitter . The ADCs 12-17 convert the video signals of the right and left frames into eight-bit codes, which enter the encoders 18-23 in parallel. The operation of the encoders is described in the analogue with 12 of Fig.5 [2]. The encoders operate synchronously, perform compression of the stream of codes with an average compression ratio per frame 4, the frequency of issuing codes from encoders is 5 MHz. Nine-digit codes come from the outputs of the encoders, the ninth digit is service, it means an identification signal in the stream of compressed codes “code of the number of equal codes in magnitude”. From encoders 18-20, the codes go to the first information input of block 24, from encoders 21-23, the codes go to the second information input of block 24 / Fig. 3/. Timing diagrams of the operation of block 24 in Fig.20. The code generator 24 converts the parallel codes into sequential ones and replaces the representation of units from pulses with positive ones in the codes R, G, B and negative in the codes R ₂ , G ₂ , and ₂ half-sinusoids of the 135 MHz monofrequency with a stability of 10 ^-7 . The third and fourth information inputs receive 16-bit sound codes from the ADC 31, 32, the fifth and sixth inputs receive the SSI and CSI codes. The CSI code is the first code in the first line of each frame, FIG. 2, while the SSI code is not, the SSI code is the first code in each line, starting from the second / FIG. 2/. Units in the codes of the right frame are represented at the output of block 24 by the positive half-sine waves of the monofrequency of 135 MHz, units in the codes of the left frame are represented at the output of block 24 by the negative half-sines of the same frequency of 135 MHz. Shaper 24 codes are executed identically to the prototype [1 figure 3], the process of its operation is described in detail in the prototype. The output from block 24 half-sine waves are modulating for the carrier frequency in the amplitude modulator 35/1 /. The lower side frequency of 1890 MHz with the information of codes for video signals and sound is radiated into the air. On the receiving side, the radio signals are received by block 59 / Fig. 4/, which is an electronically tuned channel selector, block 59 from the input circuit, a radio frequency amplifier, and a mixer, to the second input of which a frequency equal to the carrier is supplied from the synthesizer 99 frequencies / input 3 of block 59 / frequency of the transmitter 33/2025 MHz / and necessary for the detection of a single-band signal [7 p.146]. The signal from the mixer of block 59, which is the output signal of block 59, is input to the radio frequency amplifier 60, amplified to the required value, and fed to the input of a bipolar amplitude detector 61, made in accordance with the circuit diagram in FIG. 6. The diode D1 selects the positive envelope of the modulating signal diag. 9 in Fig. 20, the diode D2 from the modulating emits the envelopes of positive half-sinusoids / unit symbols of the right frame codes R, G, B / diag. 10 of Fig. 20. The diode D3 from the modulating one selects the envelopes of negative half-sinusoids / symbol units of the codes of the left frame R ₂ , G ₂ , B ₂ / diag. 11 of Fig. 20. From the first output of block 61, the detected positive half-sine waves of 135 MHz are fed to the input of the first pulse shaper 62, and from the second output of block 61, the detected negative half-sine waves of the same frequency are fed to the input of the second pulse shaper 80. Shapers 62, 80 pulses are made according to the scheme of an asymmetric trigger with emitter coupling [8 p. 209], forming rectangular pulses from harmonically changing signals. The pulses have one polarity and a duration equal to the duration of the pulses on the transmitting side. The units in the codes are again represented by pulses, the zeros by their absence. When the power is turned on, the key 100 / Fig. 4/ in the closed state. The decisive role in the working order of the receiving party belongs to the block 98 allocation of SSI. Each time an SSI code block 98 arrives at the input, a horizontal sync pulse of 25 kHz / SSI / appears at its output, which opens the key 100. The SSI also performs fine tuning of the frequency in the 99 frequency synthesizer, whose natural frequency has a stability of 10 ^-6 . The second inputs of the frequency synthesizer 99 are connected to the second group of outputs of the channel selection unit 58, and the signal from which determines the frequency output from the block 99 to the third input of the reception unit 59. A frequency synthesizer 99 generates: 5 MHz pulses from the first output, 135 MHz clock pulses from the second output, 75 kHz sound code pulses from the third, 20 MHz code sampling pulses from the fourth, and sinusoidal oscillations of the corresponding carrier frequency to the third input from the fifth block 59 of the reception, from the sixth output - pulses of a double sampling frequency of 40 MHz codes of video signals, from the seventh output - 10 MHz of the sampling frequency of sound codes. From the output of the first pulse shaper 62, the codes in serial form go to the information input of the first receiving register 63, from the second pulse shaper 80 the codes go to the information input of the second receiving register 81. The first receiving register 63 has 27 bits and receives three 9-bit R codes in a row , G, In the right frame of the stereo pair. The second receiving register 81 also has 27 bits and receives three 9-bit codes of the left frame of the stereo pair R ₂ , G ₂ , B ₂ . On receiving registers 63, 81 is 5 MHz signals U _vyd codes synchronously outputs the signals R, G, B to the registers 64, 69, 74 and signal codes R _2, G _2, B ₂ in the registers 82, 87, 92. Since these codes registers in parallel form with a frequency of 5 MHz are issued to the decoders 65, 70, 75 and 83, 88, 93, which recover 100% compressed streams of video signal codes, the recovery process is described in the prototype prototype [2 p.16 Fig.10]. Recovered streams of codes of video signals with a frequency of 20 MHz are fed to the inputs of their code doubling units / 800 × 2 /. Doubling of codes / samples in line / is performed by obtaining intermediate / middle / codes between each passing code and the one following it. Blocks of doubling codes perform the addition of codes and the division of the sum code in half, the division is performed by discarding the fallen digit in the code. The process is described in detail in the prototype [1 figure 1]. From the blocks of doubling codes 66, 71, 76, 84, 89, 94, codes in parallel form arrive at a frequency of 40 MHz in the code stores, respectively, 67, 72, 77, 85, 90, 95.

The operation of the accumulation of frame codes, Fig. 8.

The code signals in block 67 in parallel form are received at the bitwise combined first to eighth inputs of the bits of the registers 119 _1-1000 .

Filling the registers with line codes begins with the opening of the signal U _{to the} first key 120 in the first block 119 ₁ registers / Fig.9/. Key 120 passes pulses U _d 40 MHz to the input of the pulse distributor 122, the clock pulses from which are sequentially fed to the first / clock / bit inputs in parallel with eight registers 123 _1-8 . When the registers 123 are filled from the last 1600th output of block 122, the U ₃ signal closes the key 120 and is the first control output to the next block _{2 of 2} registers, the registers 123 _{1-8 of} which are filled with the codes of the second line. Over the frame period of 40 ms, row codes fill out the registers 123 of all blocks 119 _1-1000 registers / Fig. 8/. On the last block 119 ₁₀₀₀ registers the output signal is supplied in parallel to the fourth control inputs of all the blocks of registers 119 and opens into the second keys 121 are transmissive on one signal U _vyd and close keys 121.

Of all the 119 register blocks, frame codes are synchronously and parallel issued to a block of 68 pulse amplifiers. Each frame code drive has 12.8 × 10 ⁶ outputs that are connected to the same inputs in a block of 68 pulse amplifiers. The outputs of three blocks 68, 73, 78 of pulse amplifiers 38.4 × 10 ^{6 are} connected to the same inputs in the first flat panel screen 79, the outputs of blocks 86, 91, 96 of pulse amplifiers are connected to the inputs 38.4 × 10 ^{6 of the} second flat panel screen 97.

The first 106 and second 107 channels of color representation of the audio signals introduced are identical, each includes / Fig. 12/ pre-amplifier 127 connected in series, the input of which is the channel information input, three active band-pass filters 128 _1-3 audio frequencies of the corresponding ranges, the inputs of which are combined and connected to the output of pre-amplifier 127, amplitude detector 129 three _1-3 whose inputs are connected to the outputs of its active bandpass filter 128, ADC 130 _1-3 three audio signals, converting analog e sound signals into 8-bit codes, the inputs of which are connected to the outputs of its amplitude detectors 129 _1-3, 131 _1-3 are three drive sound code, the first to eighth inputs of each of which are connected to the first-eighth of its ADC outputs 130 and three block 132 _1-3 pulse amplifiers, the corresponding inputs of which are connected to the corresponding outputs of their drive 131 _1-3 codes. The first, second, third control inputs of the same name drive 131 sound codes are combined and connected: the first control U _to 25 Hz input to the output of block 103, the second control inputs to the output of 98/25 kHz /, the third to the seventh output of the 99/10 MHz block /, the control inputs U _{d of the} ADC 130 are combined and connected to the seventh output of the 99/10 MHz / block. The outputs of blocks 132 _1-3 pulse amplifiers of the first channel 106 are connected to the corresponding inputs of the first screen 79, the outputs of blocks 132 _1-3 pulse amplifiers of the second channel 107 are connected to the corresponding inputs of the second screen 97. Color display of stereo sound is carried out on two screens in their upper parts on 250 lines each. The color image of the sound is created in each frame by mixing the colors of the sound display of the three ranges of sound frequencies in the corresponding doses of the base colors R, G, B. The following option for dividing the sound frequency band with three active band-pass filters is accepted: the first range of 30-500 Hz is represented by red R color, the second the range of 500-3500 Hz is represented by green G color, the third range of 3.5-15 kHz is represented by blue B. Each element of the screen matrix forms a pixel color by mixing the colors of three emitting cells, the radiation brightness which are determined by the values of binary codes entering the emitting cells from the drives 131 sound codes. The input of the pre-amplifier 127 of the first channel of the color display of audio signals is connected to the output of the first channel 104 sound reproduction, the input of the pre-amplifier 127 of the second channel 107 of the color display of audio signals is connected to the output of the second channel 105 of the sound reproduction. The sound signals from the output of the pre-amplifier 127 are fed to the inputs of three active band-pass filters 128: the band-pass filter 128 ₁ selects the sound signals in the frequency range 30-500 Hz, the band-pass filter 128 ₂ outputs the sound signals in the frequency range 500-3500 Hz, and a band-pass filter 128 ₃ emits sound signals of the frequency range 3.5-15 kHz at the output. Amplitude detectors 129 _1-3 detect the signals arriving at their inputs. The ADC 130 _1-3 convert the detected signals into 8-bit codes, allowing you to use the same matrix elements in screens 79, 97 as for 8-bit codes of video signals. From the outputs of the ADC 130 _1-3, codes of sounds with a frequency of 10 MHz go to drives 131 _{1-3 of} codes of sound that are identical, each includes / Fig. 13/ blocks 133 _1-250 registers by the number of lines in the upper part of screens 79, 97 . Information input drive 131 are audio codes bitwise combined first-eighth input unit 133 registers _1-250, control inputs are: first - control input U _to 25 Hz of the first block of registers 133 _1, the second - the combined second control inputs U _vyd blocks 25 kHz 133 _1-250 registers, third - combined third managing All inputs U _d 10 MHz blocks 133 _1-250 registers. The control output of each previous block of registers is the first control input for each subsequent block of registers, the control output of the last block 133 ₂₅₀ registers is connected in parallel to the fourth control inputs of all blocks of 133 registers. The outputs of the drive 131 sound codes are the parallel outputs of all 133 _1-250 registers, total outputs from the block 3.2 × 10 ⁶ / 12.8 × 10 ³ × 250 /. Blocks 133 of the registers are identical, each includes / FIG. 14, 15 / first 134, second 135 keys, a distributor 136 pulses and eight registers 137 _1-8 , each of 1600 digits according to the number of samples in a row. The information inputs of the block 133 of the registers are bitwise combined the first to eighth third inputs of the bits of the eight registers 137, the outputs are the parallel outputs of all the bits of the eight registers 137: total outputs 12800/1600 × 8 /. The outputs of all register blocks are outputs in each drive 131 _1-3 sound codes, of which 12.8 × 10 ³ × 250 _lines = 3.2 × 10 ₆ .

The control inputs in the block 133 registers are: the first is the first control input U _from 25 Hz of the first key 134 / Fig.14/, the second is the signal input 25 kHz U _{output of the} second key 135, the third is the signal input 10 MHz U _{d the} first key, fourth - the first control input U _{from the} second key 135. The output of the first key 134 is connected to the input of the pulse distributor 136, the outputs of which are sequentially from the first to 1600 are connected to the first / clock / bit inputs in parallel with eight registers 137. The last 1600th output of block 136 is the control output registers of block 133 ₁ s 133 in the next block ₂ and connected to its first control input of the first switch 134, 14. Yield of the second switch 135 is connected in parallel to the control inputs of the second eight bits of parallel registers 137 and to the second control input of its U ₃ key 135, extending the first pulse U _vyd outputs all signals with eight bits of registers 137 and closes switch 135. The outputs of accumulators 131 _1-3 /fig.12/ connected to data inputs of its blocks 132 _1-3 pulse amplifiers, each of which includes a pulse amplifier according to the number of outputs from the drive sound codes 131 3.2 × 10 ^6/1600 × 8 × 250 /. With the end of the frame period of 40 ms in the drives 131 _1-3 sound codes, all sound codes for the duration of the frame are concentrated. With the arrival of a signal from the last block 133 ₂₅₀ to the fourth control inputs of blocks of registers 133 / Fig. 1/, all sound codes of the frame are simultaneously sent to their blocks 132 _1-3 pulse amplifiers, the outputs of which amplified signals of units of sound codes with a duration of 40 ms arrive in parallel and synchronously to the inputs of their matrix elements in the upper parts of screens 79, 97 and form color images of sound signals accompanying video frames.

The operation of the drives 131 _1-3 sound codes, Fig.13.

The signals of the discharges from the ADC 130 arrive in parallel to the information inputs of all blocks of 133 registers. The filling of blocks 133 is sequential, filling begins with the opening of the signal U _{to the} first key 134 in the first block 133 ₁ registers / Fig.14/. The key 134 passes pulses U _d 10 MHz to the input of the pulse distributor 136, eight registers 137 are filled, after filling them, the 1600th signal from block 136 closes the key 134 and opens the first key 134 in the next block _{2 of 2} registers, the registers of which are filled with sound codes second row etc. For a frame period of 40 ms / 25 Hz / sound codes are filled sequentially all registers 137 of all blocks of 133 _1-250 registers. From the last block 133 of ₂₅₀ registers, the output signal opens / Fig. 13/ parallel keys 135 in all blocks 133 to _1-250 registers, which pass one signal U _output , which synchronously and parallelly output sound codes from blocks 133 of registers to blocks 132 _{1 -3} , in which pulsed amplifiers generate pulses of codes in amplitude and duration of 40 ms and output them to the inputs of the matrix elements in the upper part of the screen 79/97 /. The viewer perceives the color display of sound signals from both screens through glasses 108 / Fig. 4/ and receives a volumetric color display of sounds accompanying the surround video image from the screens. Video modes at the top of the screens are 25 Hz × 1600 _count × 250 _lines , resolution 0.4 × 10 ⁶ pixels. The right 79 and left 97 flat-panel screens are identical, each consists of two parts: the lower part is designed to reproduce video information of stereo pairs and contains 1000 lines with 1600 samples in each, the resolution of the frame is 1.6 × 10 ⁶ pixels / 1600 × 1000 /, the video mode in it 25 Hz × 1600 _counts × 1000 _lines , the upper part of the screen is designed for color reproduction of sound signals and contains 250 lines with 1600 counts in each line. The matrix elements in both parts of the screens are identical, each matrix element, as in the prototype, [1 Fig. 12, 13, 15] includes one LED 138 of a white glow and a correspondingly shaped opaque housing 139, combining three identical emitting cells 140, 141 , 142 / Fig. 16, 17 /. The upper 141 emitting cell emits green G color, the lower left 140 emits red R color, the lower right 142 emits blue B color. The cells are made identically as in the prototype, each contains (Fig. 17, 18) in the front of the cell a microlens 143, along the optical axis of which neutral microfilters 144 _1-8 with attenuation / absorption / radiation coefficients the order of reduction according to the principle of binary code from the first to the eighth neutral microfilter, and contains from the first to eighth micropiezoelectric elements 145 _1-8 , one end of which is rigidly fixed to the wall of the housing of the matrix element, the second free end appropriately connected to its neutral microfilter. In the output end of the housing 139 along the optical axis of the microlens 143 there is a color filter 146 of one of the basic colors R, G, B, which determines the color of the radiation of the cell 140, 141, 142, Neutral microfilter 144 _1-8 have emission attenuation coefficients, respectively, of their discharge weight in the code is given in table 1. The emitted plane of the LED 138 is located in the focal planes of the microlenses 143 of the emitting cells, the radiation of the LED 138 (Fig. 17) is directed by the microlens 143 to the sequentially located neutral microfilters 144 _1-8 .

The principle of operation of the emitting cell is that each neutral microfilter attenuates the radiation according to the weight of its discharge, the attenuation coefficients decrease by the principle of a binary code from the first to the eighth. The inputs of the micropiezoelectric elements 145 _1-8 are the control inputs of the emitting cell. In the absence of control signals / code units / at the inputs of micropiezoelectric elements 145, the microfilter 144 _1-8 block the radiation flux to a level below the sensitivity of human vision. Upon receipt of a control signal to micropiezoelectric element 145, its free end bends and rotates the microfilter 144 through 90 °, the radiation flux passes without attenuation to the next neutral microfilter 144. After the eighth microfilter 144 _{8, the} radiation passes through a color filter 146, becomes colored in its color and participates in the formation color tone and pixel brightness. Emitting cells are made using microtechnologies and should have meager sizes, for example, in height and width of 0.5 × 0.5 mm, the length of the element will be determined by the perfection of microtechnologies of 8 ... 10 mm. On Fig shows an example of conversion of code 10110110 in the brightness of the radiation. Cells of all elements of the matrix of the lower and upper parts of the screen work in parallel by incoming pulses from pulse amplifiers. Matrix elements are made separately, and screens from them are dialed. The arrangement of the matrix elements in the screen of Fig. 19. The identity of most electronic circuits in the receiving part blocks allows them to be implemented with microcircuits. As LEDs of white glow, LEDs of the PL ED technology can be used [9 p. 43].

The operation of the stereo system.

PEC 1 of the transmitting side generates analog video signals of the right and left frames of the stereo pair. ADCs 12-17 convert analog video signals into 8-bit codes, encoders 18-23 compress the code stream with a coefficient of 4 per frame, then the video signal codes in parallel form go to the first and second information inputs of the code generator 24, from the first output the codes are in successive form of positive and negative sine waves are fed into the amplitude modulator 35 of the transmitter 33 of the radio signals. The modulated lower side frequency of 1890 MHz is broadcast. At the receiving side, the radio signals are received by the receiving unit 59, amplified in block 60, and fed to a bipolar amplitude detector 61, from the first output of which the detected positive half-sine waves are supplied to the pulse shaper 62, from the second output negative half-sine waves are supplied to the pulse shaper 80. Block 98 selects the clock pulses of the lines / SSI /, they fine-tune the frequency synthesizer 99 frequencies and starts issuing the corresponding control signals. The codes of the right and left frames of the stereo pair are distributed over their processing channels. The decoders in each channel restore the original 20 MHz code streams, blocks 66, 71, 78, 84, 89, 94 double the number of samples in the lines from 800 to 1600. For the duration of the first frame, 40 ms drives 67, 72, 77, 85, 90 , 95 codes concentrate frame codes within themselves, which are then synchronously output into pulse amplifier units, in which they are amplified, receive a duration of 40 ms, and all arrive in parallel to the inputs of the lower parts of screens 79, 97, reproducing the right and left frames in parallel, the viewer receives both images in parallel through glasses 108 and gets 3D image of a stereo pair. The stereo sound of the television broadcast is reproduced by the first 104 and second 105 channels on the upper parts of the screens 79, 97 in color, observed by the viewer also through the glasses 108, that is, color and surround. As a result, the viewer receives video and audio information in a new quality.

Information sources

1. RF patent No. 2410846 C1 class. H04N 7/00 bull. No. 3 dated January 27, 2011, a prototype.

2. RF patent No. 2356179 C1 class. H04N 15/00 bull. 14 from 05.20.09, analog.

3. Kolesnichenko OV Shishigin I.V. p.6 of Fig.5, 6, p.5 of Fig.3, p.16 of Fig.10. PC hardware. 5th ed., St. Petersburg, 2004, p. 832-833.

4. V.I. Ilyin. Remote control and telemetry. M. 1982, p. 269, 274.

5. RF patent No. 2298297 C1 class. H04N 15/00, bull. 12 dated 04/27/07, analogue, p. 5 of Fig. 7.

6. Radio transmitting devices. M.S. Shumilin et al. M, 1981, p. 234, 235.

7. Radio communications, broadcasting and television. Ed. A.D. Fortushenko, M, 1981, p. 146.

8. V.F. Barkan, V.K. Zhdanov. Amplification and pulse technology, M., 1981, p. 209.

9. Magazine "Home Computer" No. 12, 2006, p. 43.

Claims (1)

A stereo television system containing a transmitting side as part of a photovoltaic converter / photomultiplier / including a first lens and a first PZI matrix / charge injection device / located in the focal plane of the first lens and three outputs of which are connected to the inputs of the first three pre-amplifiers, the second lens and the second the FDI matrix located in the focal plane of the second lens and the three outputs of which are connected to the inputs of the second three pre-amplifiers, the outputs of which and the outputs of the first three pre-amplifiers measuring amplifiers is the outputs of the photomultiplier tubes containing the first to sixth analog-to-digital converters / ADCs / video signals, the inputs of which are connected to the outputs of the corresponding preliminary amplifiers of the photoconductors, the first to sixth encoders, the first to eighth information inputs of which are connected to the first to eighth outputs of the corresponding ADC video signals, code generator, the first information input of which is connected to the first to ninth outputs of the first three encoders, the second information input is connected to the first to ninth outputs of the second tr x encoders, the first ADC of the sound signals, the output of which is connected to the third information input of the code generator, the second ADC of the sound signal, the output of which is connected to the fourth information input of the code generator, the first self-propelled pulse distributor, the outputs of which are combined and connected to the fifth information input of the code generator, and the input of the first self-propelled pulse distributor / SRI / is connected to the second output of the code generator, the second SRI, the outputs of which are combined and connected to the sixth information to the input of the code generator, which contains the sinusoidal oscillation generator and the frequency synthesizer, the first and second keys and the radio signal transmitter, the first output of the frequency synthesizer is connected in parallel to the control inputs of the first and second keys, to the fourth control input of the code generator and to the first input of the second SRI, the second output / 5 MHz / frequency synthesizer is connected in parallel to the first control input of the code generator, to the control inputs / U _output / six encoders and to the first control the inputs of the first and second ADCs of the sound signals, the third output of the frequency synthesizer is connected in parallel to the third control inputs of the first and second ADCs of the sound signals, the fourth output of the frequency synthesizer is connected to the second / 135 MHz / control input of the code generator, the fifth output is connected in parallel to the second control inputs the first and second ADCs of the sound signals, to the third control input of the code generator and to the signal input of the first key, the sixth output / 20 MHz / frequency synthesizer is connected in parallel to the signal input in orogo key and to the control inputs / U _d / six ADC video signal, the first switch output is connected in parallel to first inputs of first and second matrices FDI, the second inputs of which are connected in parallel to the output of the second switch, the radio transmitter comprises a serially coupled amplifier carrier frequency, which input is connected to the seventh output of the frequency synthesizer, an amplitude modulator, an output amplifier and an antenna, the second input of the amplitude modulator is connected to the first output of the code generator, and containing the receiving side the control unit / selection of channels /, the path for receiving and processing codes of video signals, the channel for generating control signals, the first and second flat-panel screens, the first and second channels for reproducing sound and glasses of separate fields of view, the path for receiving and processing codes of video signals includes a series-connected antenna, a unit of receiving radio signals, a radio frequency amplifier and a bipolar amplitude detector, first and second channels for processing video signal codes, a group of second inputs of a block for receiving radio signals under It is connected to the corresponding outputs of the first group of outputs of the control unit / channel selection /, the first channel for processing video signal codes includes a first pulse shaper connected in series, the input of which is connected to the first output of a bipolar amplitude detector, the first receiving register of twenty-seven bits and three color signal channels: channel signal R, channel signal G, channel signal B, the channels are identical, each includes a series-connected register, the inputs of which are connected to nine respectively the existing outputs of the first receiving register, a decoder, a code doubling unit, a frame code storage unit and a pulse amplifier unit of the corresponding number of pulse amplifiers and a first flat panel screen, the second video signal code processing channel includes a second pulse shaper connected in series, the input of which is connected to the second output of a bipolar amplitude detector , the second receiving register of twenty-seven bits and three channels of color signals: signal channel R ₂ , signal channel G ₂ , signal channel V ₂ , ka The channels are identical, each contains a series-connected register, the inputs of which are connected to the nine corresponding outputs of the second receiving register, a decoder, a code doubling unit, a frame code storage unit and a pulse amplifier unit of the corresponding number of pulse amplifiers and a second flat panel screen, the first and second flat panel screens are made equally, each comprises a number of matrix elements on a frame resolution of 1.6 × 10 ^6/1600 · 1000 /, the matrix element comprises a single LED and white light corresponding pho we are an opaque case in which three identical emitting cells are located, the upper one emits green G, the lower left emits red R, the lower right emits blue In color, the emitting cells are identical, each contains a microlens in the front end of the case, sequentially located along the optical the axis of the microlens one after the other from the first to the eighth neutral microfilter with radiation absorption coefficients in decreasing order from the first to the eighth neutral microfilter according to the principle of binary code and it contains from the first to the eighth micropiezoelectric elements, one end of each is fixed to the wall of the matrix element body, the second free end of the micro piezoelectric element is suitably connected to its neutral microfilter, in the output end of the housing and along the optical axis of the microlenses there is a color filter of one of the primary colors R, G , B, the control inputs of the emitting cell are the control inputs of the first to eighth micro-piezoelectric elements connected to the outputs of the corresponding pulse amplifiers in the corresponding blocks of pulse amplifiers, glasses of separate fields of view represent a frame with ear arches, the windows of the glasses do not have glasses, are interconnected by a movable vertical axis and rotate relative to each other, each window of the glasses has a conical lens hood at the end of a rectangular shape to fit the screens, hoods of two parts: the first part is screwed into the window of glasses, the second part is movable extends and pushes into the first, changing the length of the hood, the channel for generating control signals contains sequentially connected block selection horizontal sync pulses / SSI / and a frequency synthesizer, as well as a series-connected key, pulse counter and decoder, and a frame sync selection block / CSI /, the first input of the SSI selection block is connected to the output of the first pulse shaper, the second input is connected to the output of the second pulse shaper, the first input of the CSI selection block is connected to it, the second input of which is connected to the output of the first pulse shaper, the output of the SSI selection block is connected to the first input of the frequency synthesizer and to the first control key input to it, the second group of inputs of the frequency synthesizer is connected to the second group of outputs of the control unit / channel selection /, the fifth output of the frequency synthesizer is connected to the third input of the radio signal receiving unit, the first output of the frequency synthesizer is connected in parallel to the signal input of the key, to the second control inputs U _output the first and second receiving registers, to the control inputs of the registers of the first and second channels of code processing and to the corresponding control inputs of the decoders, the second output of the frequency synthesizer / 135 MHz / is connected to parallel to the first control inputs of the first and second receiving registers, the fourth output of the / 20 MHz / frequency synthesizer is connected to the corresponding control inputs of the decoders and the control inputs of the code doubling units, the sixth output / 40 MHz / is connected in parallel to the third control inputs / U _d / of the code stores frame, the second control inputs of which are connected in parallel to the output of the block selection of horizontal sync pulses, the output of the block of selection of frame sync pulses is connected in parallel to the first control inputs of drives frame codes, the information input of the first sound reproducing channel is connected to the output of the first pulse shaper, the information input of the second sound reproducing channel is connected to the output of the second pulse shaper, the first, second, third and fourth control inputs of the same name of both sound reproducing channels are combined and connected respectively to the first output the decoder, the second output of the decoder, to the second output of the frequency synthesizer and to the third output / 75 kHz / frequency synthesizer, the second control input U ₃ keys and the control input of the pulse counter / U ₀ / are combined and connected to the second output of the decoder, the output of the first sound reproduction channel is connected to the input of the speaker Gr ₁ , the output of the second sound reproduction channel is connected to the input of the speaker Gr ₂ , characterized in that at the reception side are introduced the first and second color channels of sound signals that are performed identically, each includes a series-connected pre-amplifier, the input of which is an information input connected and connected to the output of its channel of sound reproduction, three active bandpass filters of sound frequency of the corresponding ranges, the inputs of which are combined and connected to the output of the preamplifier, three amplitude detectors, the inputs of which are connected to the outputs of their active bandpass filters, three ADC sound signals, the inputs of which their outputs are connected to amplitude detectors, the control input U _d ADC audio signals are combined and connected to the seventh output of the frequency synthesizer receiving side, three accumulate I have sound codes, the first to eighth inputs of each of which are connected to the first to eighth outputs of your ADC audio signals, the first, second and third control inputs of the same name of the sound code drives are combined and connected: the first to the output of the KSI / 25 Hz / isolation block, the second - to the output of the SSI isolation block / 25 kHz /, the third - to the seventh output / 10 MHz / frequency synthesizer, and three pulse amplifier units, each containing pulse amplifiers according to the number of outputs of the sound code storage device, the corresponding inputs of the pulse amplifier blocks are connected they are connected to the corresponding outputs of their drive of sound codes, and each block of pulse amplifiers has outputs by the number of pulse amplifiers, the drives of sound codes are identical, each includes two hundred and fifty register blocks, the information input of the drive of sound codes is the bit-wise combined first to eighth information inputs of all register blocks , the control inputs are: the first is the first control input / 25 Hz / of the first block of registers, the second is the combined second control inputs / 25 kHz / block of registers, t them - the combined third control inputs / 10 MHz / register blocks, the control output of each previous block of registers is the first control input for each subsequent block of registers, the control output of the last / 250th / block of registers is connected in parallel to the fourth control inputs of all register blocks, outputs sound code storage devices are parallel outputs of all register blocks, register blocks are identical, each contains the first and second keys, a pulse distributor and eight registers, each of 1600 poisons, the information input of the register block is the bit-wise combined first to eighth third inputs of the bits of the eight registers, the outputs are the parallel outputs of all the bits of the eight registers, the first control input of the register block is the first control U _{from the} input of the first key, the second is the signal input of the second key, the third is the signal input of the first key, the fourth is the first control U _from , the input of the second key, the output of the first key is connected to the input of the pulse distributor, the outputs of which, starting from the first are connected to the first / clock / inputs of the bits of eight registers, the last / 1600 / output is connected to the second control U ₃ input of the first key and is the first control output of the register block, connected to the first control input of the first key in the next register block, the output of the second key is connected parallel to the second inputs of the eight bits in parallel registers and to the second control input of its U ₃ key, each register unit outputs are connected to respective inputs of its block pulse amplifiers, trans first and second flat panel screens are identical, each consist of two parts, the first part - the lower stereopair performs playback video frames with a resolution of 1.6 × 10 ⁶ pixels / 1000 · 1600 / and contains 1.6 x 10 ⁶ cell matrices unit outputs pulse amplifiers the first channel for processing video signal codes are connected to the corresponding inputs of the lower part of the first flat panel screen; the outputs of the pulse amplifier block of the second channel for processing video signal codes are connected to the corresponding inputs of the lower part of the second plane panel the first screen, the second portion of the screen - the upper performs color mapping of audio signals with resolution of 0.4 x 10 ⁶ pixels / _lines 250 · 1600 /, contains 0.4 x 10 ⁶ cell matrix screen, the outputs of the pulse amplifier block of the first color display channel audio signals connected to the corresponding inputs of the upper part of the first flat panel screen, the outputs of the block of pulse amplifiers of the second channel for the color display of sound signals are connected to the corresponding inputs of the upper part of the second flat panel screen.

Images