RU2473182C1 - Device for three-dimensional colour display of audio stereo signals - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: result is achieved by simplifying the composition of the device using three band-pass filters of audio frequency, introducing into each channel a binary code-to-brightness code converter and making matrix elements in screens from one corresponding emitting cell.

EFFECT: realising colour display of stereo sound on two screens and suitability of the device for mass use in everyday life.

10 dwg

Description

The invention relates to color music devices and can be used to accompany two-channel stereo phono surround color display.

The prototype adopted a volumetric color display device for stereo audio signals on two screens [1], containing two channels, each of which includes a pre-amplifier in series, an audio frequency band filter / SP / including nine active audio bandpass filters, a detector block containing nine amplitude detectors, the input of each of which is connected to the output of its active bandpass filter in the RF in the block of bandpass filters of the RF, includes nine ADCs, the input of each of which connected to its output in the detector block, includes nine drives of sound codes, nine blocks of pulse amplifiers, each of which contains 8 × 10 ⁶ pulse amplifiers and includes a fixed flat panel screen. The second channel includes a right movable flat panel screen. The audio frequency band in each channel in the block of band-pass filters of the SP is divided into nine corresponding ranges. The left and right screens are placed in the frame, whose lower part is under the right screen has rollers for a small displacement thereon right screen left and right screens are identical, each comprising an array of elements, which in the screen by the number of resolution 10 ^6/1000 × 1000 / . Each element of the matrix forms a pixel from nine emitting cells and includes an opaque case, combining nine emitting cells arranged in three rows. Each cell contains a housing, in the front end of which there is a microlens, in the output end of the housing of the corresponding color there is a color filter, and between the microlens and the color filter there is an aperture body with eight slots, in which eight neutral micro-filters are attached to their micropiezoelectric elements in the code number . The principle of operation of the emitting cell is that each neutral microfilter attenuates the radiation flux after the microlens, correspondingly to the weight of its discharge in the code. Radiations of nine cells are mixed at the output of the matrix element, a pixel is formed by brightness and color tone, respectively, of nine codes. Radiations of matrix elements create color images of sounds on two screens, which the viewer observes through glasses of separate fields of view. According to the color and time differences on the two screens, the viewer perceives the color display of the music as surround. The disadvantages of the prototype are the complexity of the device with nine sections of sound frequencies, the implementation of the matrix elements from nine emitting cells limits the resolution of the screens and increases their size.

The purpose of the invention is to simplify the device, increase the resolution of screens, reduce their size, create a device suitable for mass use in everyday life.

The essence of the claimed device, containing a clock generator and a frequency divider, is that each channel of the device includes a series-connected block of band-pass filters of three active band-pass filters, a block of detectors of three amplitude detectors, three ADCs, three drives of sound codes and three blocks of pulse amplifiers , and three “binary code - brightness code” transducers are introduced into each channel, each matrix element from one emitting cell emitting three color radiation of red, green during the frame period blue.

The technical results are to simplify the composition of the device, increase the resolution of the screens, reduce their size and the ability to use the device in everyday life in conjunction with any sound-reproducing device.

The structural diagram of the device of figure 1, the Converter circuit "binary code - brightness code" in figure 2, the key block in figure 3, the storage of sound codes in figure 4 _1-3 , the block of registers in figure 5 and 6, the General view of the matrix element and the emitting cell in Fig.7, the principle of operation of the emitting cell in Fig.8.

The video mode on the screens is 1000 _lines × 1000 _counts × 25 Hz. The sampling rate of audio codes in the ADC is

f _d = 1000 × 1000 × 25 Hz = 25 MHz,

where 1000 is the number of lines in the frame / in the screen /,

1000 - the number of samples per line, 25 Hz - frame rate.

The volumetric color display device for stereo audio signals contains (Fig. 1) a series-connected clock generator 1, a frequency divider 2 and a key block 13, two identical channels, a frame 3 in which two flat-panel screens are located, and glasses with 4 separate fields of view. The first channel includes / Fig. 1/ a series-connected pre-amplifier 5, the input of which is the first information input of the device, a block 6 of audio bandpass filters / SP / containing three active bandpass filters SP, band ranges highlighted by bandpass filters, in table 1, includes a block 7 amplitude detectors containing three amplitude detectors, the input of each of which is connected to the output of its active bandpass filter SP in block 6, the outputs of three amplitude detectors are the first or third output E unit 7 includes three 8 _1-3 ADC, each having its input connected to the output unit 7 in the amplitude detector comprises three transducers 9 _1-3 "binary code - the code brightness", the first to eighth inputs each respectively connected to the first to eighth outputs of its ADC 8, includes three drives of 10 _1-3 codes, the first to eighth inputs of each are connected respectively to the first to eighth outputs of its converter 9, includes three blocks of 11 _1-3 pulse amplifiers, each of which contains 9 × June ¹⁰ includes a pulse amplifier and left no odvizhny Flat screen 12 whose inputs are connected to outputs of three blocks 11 of the pulse amplifier, the screen 12 has 27 × ¹⁰ June inputs / 3 × 9 × ¹⁰ June /.

Table 1. Ranges, Hz 50-900 900-6000 6000-12000 Emission color red green blue

The second channel includes / Fig. 1 / connected in series preamplifier 14, the input of which is the second information input U2 device, block 15 bandpass filters, containing three active bandpass filters, frequency bands identical to those of bandpass filters in block 6, includes block 16 amplitude detectors, containing three amplitude detectors, the input of each of which is connected to the output of its bandpass filter SP in block 15, the outputs of three amplitude detectors are outputs of block 16, includes three ADCs 17 _1-3 , the input of each is connected to its output in block 16 amplitude detectors, includes three converters 18 _1-3 "binary code - brightness code", the first to eighth inputs of each of them are connected respectively to the first to eighth outputs of its ADC 17, includes three drives 19 _{1 -3} codes, the first-eighth inputs of each are connected respectively to the first-eighth outputs of its “binary code - brightness code” converter 18 _1-3 , includes three blocks of 20 _1-3 pulse amplifiers, each of which contains 9 × 10 ⁶ pulse amplifiers , and includes the right movable loskopanelny screen 21 whose inputs are connected to outputs 27 × ¹⁰ June three blocks 20 _1-3 pulsed amplifiers. The left 12 and right 21 screens are located in the frame 3, the lower part of which under the right screen 21 has support rollers 22 for moving the right screen 21 along them left or right by 15 cm. Converters 9 _1-3 and 18 _{1-3 are} made identically, each contains / Fig. 2/ an opaque case 23, in which eight keys 24 _1-8 are arranged according to the number of bits in the sound code, a light pulse emitter 25, representing a matrix of eight white LEDs, fastened in the corresponding case, the inputs of the pulse LEDs are connected to the outputs their veins 24, the first control inputs _{of the} U which are information converter inputs 9 and 18 respectively connected to the outputs of the first to eighth bits of the ADC 8/17 /. The signal inputs of the keys 24 _{1-8 are} combined and are the control input of the converter 9/18 /, which is connected to the second 25 MHz output of the frequency divider 2, the outputs of the keys 24 _{1-8 are} connected to the inputs of their LEDs, the pulses from the keys power the LEDs. The output of each key 24 is also connected to its second control input U _s , closing it after the pulse passes to the LED. Each pulsed LED on the emitting side has a neutral filter with a radiation attenuation coefficient of the corresponding code discharge, attenuation coefficients in table 2. Converter 9/18 / includes an internal opaque housing 26, in the upper part of which a lens 27 is fixed, whose optical axis coincides with the optical the axis of the light pulse emitter 25. On the optical axis of the lens 27 at an angle of 45 ° to it are arranged sequentially one after another at an appropriate distance and rigidly fixed There are eight translucent micromirrors 28 _1-8 , each of which has a beam splitting coating, which fulfills the ratio of reflected radiation to transmitted to the next micromirror as 1: 0.5 2.

table 2 Discharge number one 2 3 four 5 6 7 8 % pass filter one hundred% fifty% 25% 12.5% 6.25% 3.12% 1.56% 0.78% Attenuation coefficient 0 0.5 0.75 0.87 0.937 0.968 0.984 0,992 Multiplicity of the filter 0 ^x 2 ^x 4 ^x 8 ^x 16 ^x 32 ^x 64 ^x 128 ^x

On the side of the housing 26, to which the micromirrors 28 are rotated, there are eight corresponding photodetectors 29 _1-8 , which receive reflected radiation and emit electrical impulses to their pulse amplifiers 32, of which in block 30 there are eight 32 _1-8 and nine keys 33 _1-9 , block 30 has a second opaque case 31. The outputs of the keys 33 _1-8 are informational first to eighth outputs of the Converter 9/18 /. Output pulse amplifier 32 ₁ is connected to the first control input U _{from the} first switch 33 ₁ and the parallel connected to the second control input U _of the second switch 33 ₂ is also connected to pulse amplifiers 32 _3-7 33 _2-8 to the keys, the output of the last pulse amplifier 32 _{8 is} connected in parallel to the first control inputs U _from keys 33 ₈ and 33 ₉ . Signal inputs _1-8 keys 33 are combined and connected to the output ₉ key 33, second control input U _s which is connected to its output, the transmitted pulse closes the switch 33 _9. The signal input of the key 33 _{9 is} connected to the control input of the binary binary code-brightness code converter, the key 33 ₉ closes immediately after the 25 MHz pulse passes to the signal inputs of the keys 33.

The operation of the Converter "binary code - code brightness".

The signals from the outputs of the ADC discharges 8/17 / synchronously open the keys 24 _1-8 , through which a 25 MHz pulse passes from block 2 and energizes the white LEDs in the emitter 25. The LEDs synchronously produce light pulses with brightness corresponding to the weights of the discharges served by the skin, table 2. The total flux of the light pulse through the lens 27 enters the centers of the translucent micromirrors 28, and the reflected radiation arrives at the photodetectors 29, from the outputs of which the electric pulses arrive at their pulse amplifiers 32 _1-8 , from which sy supplied to the first control inputs of the U _of its keys _1-8 and 33 to the second control inputs of the U _of the previous keys 33 and close them. And the pulse from the pulse amplifier 32 ₈ opens the key 33 ₉ . The process goes with the speed of light propagation. The beam brightness after each micromirror 28 is attenuated twice, which corresponds to the principle of a binary code, a code, by the time the last reflected ray arrives, for example, from a translucent micromirror 28 _{3 /} Fig. ₂ /, the keys 33 ₈ to 33 ₄ will already be closed, and the keys 32 ₂ , 32 ₁ will not be open yet: the brightness of the beam has weakened after passing through the micromirrors 28 _8-3 so much that the photodetectors 29 ₂ and 29 ₁ no longer work. The key 33 _{9 is} opened by the signal U _from the output of the pulse amplifier 32 ₈ when the first micromirror passes through 28 ₈ and remains open until a 25 MHz pulse arrives from block 2. With a 25 MHz pulse it arrives in parallel to the signal inputs of all keys 33 _8-1 , of which at that moment only one key 33 _{3 is} open, keys 33 _8-4 will already be closed, keys 33 _2-1 will not be open yet, the pulse will go through public key 33 ₃ to the output of converter 9, the output of which will be code 00100000. At the outputs of the converters 9, 18, the codes will be with a signal “1” in one category , in the remaining digits zeros. The drives 10 _1-3 and 19 _1-3 codes are identical, each contains / Fig. 4 _1-3 / blocks 37 _1-1000 registers according to the number of lines in the frame. The first information-eighth inputs are bitwise combined first to eighth inputs of all registers block 37, and the ninth information blocks 37 registers also combined and connected to the control input unit 10 2 _{1-3 1-3} /fig.4 /. The outputs of accumulators 10 _1-3 and 19 _1-3 Codes are parallel outputs of the first to 9000 th units of registers 37, only the outputs from the code storage 9 × 10 ^6/9000 × 1000 /. The control inputs are: the first is the first control input U _to 25 Hz of the first block 37 ₁ registers / Fig. 4 ₁ /, the second is the combined second control inputs U _d 25 MHz of blocks of 37 registers, the third is the combined third control inputs U _output 75 Hz of blocks 37 registers, and the third control inputs of blocks 10 _{1-3 of the} registers of the first channel are connected respectively to the outputs 1, 2 and 3 in block 13 of the keys / Fig. 1/, and the third control inputs U _output in blocks 19 _{1-3 of the} second channel are also connected to outputs 1, 2 and 3 in block 13 keys, fourth - combined fourth control inputs of registers block 37 connected to the output 37 of the last block ₁₀₀₀ registers. The control input of each previous block of 37 registers is the first control input for each subsequent block of 37 registers. The blocks of 37 registers are identical, each includes / Fig. 5, 6 / first 38 and second 39 keys, a distributor of 40 pulses and nine registers 41 _1-9 , each of a thousand bits in the number of samples in a row. The information inputs of block 37 are the bitwise combined third inputs of the bits of the nine registers 41. The outputs are the parallel outputs of all the bits of the nine registers 41, total outputs 9000: 9 bits × 1000. The parallel outputs of the three drives codes 10 _1-3 and 19 _1-3 in each channel are 3 × 9 × 10 ⁶ = 27 × 10 ⁶ . The managing unit 37 registers /fig.5/ inputs are: first - the first control input U _from the first key 38, second - U _d key signal input 38, a third - a signal input U _vyd 75Hz key 39 connected to the corresponding output block 13 keys / Fig. 1/, fourth - the first control input U _from key 39. The output of the first key 38 is connected to the input of the pulse distributor 40, the outputs of which, starting from the first, are connected in series to the first / clock / bit inputs in parallel with nine registers 41, the last output 1,000th connected to the input U _of Initia of the key 38 and is a control output of the next block register 37 _2. Yield of the second switch 39 is connected in parallel to the second inputs of the nine bits of the register 41 and to the second control input U _of the second switch 39, a transmitted pulse U _vyd closes switch 39. The outputs of accumulators codes 10 _1-3 and 19 _1-3 are connected to inputs of blocks 11 _1-3 and 20 _1-3 pulse amplifiers, each of which includes pulse amplifiers according to the number of outputs from block 10 and 19: 9 × 10 ⁶ . The outputs of three blocks 11 _1-3 and three blocks 20 _1-3 are each 27 × 10 ^6/3 × 9 × 10 ⁶ /, respectively connected to the same number of inputs 27 × 10 ^{6 of} their screens 12 and 21.

The operation of the drives codes 19 and 10, Fig.4, 5.

The signals of the first to eighth digits from the converters 9 _1-3 , 18 _1-3 are fed to the first to eighth information inputs of blocks 37 of the registers / Fig. 5/, the ninth information input of blocks 37 receives 25 MHz pulses from the second control input of the code storage unit U _d which are the control impulses of introducing into the radiation flux (Fit.7) a color micro-filter for coloring the radiation matrix emanating from the element. The filling of the registers 41 _{1-9 with the} codes of the first line begins with the opening by the signal U _to 25 Hz of the first key 38 in the first block 37 _{1 of the} registers / Fig. 5/. Key 38 transmits pulses U _d 25 MHz pulse distributor 40 input clock pulses with which sequentially arrive at the clock inputs of the nine registers 41. Registers 41 filling the first row with the last audio code output unit 40 closes the signal U _of the key 38 and the output signal opens the key 38 in the next block 37 ₂ registers, registers 41 _{1-9 of} which are filled with codes of the second line. For a frame period of 40 ms, all registers 41 in all blocks of 37 _1-1000 registers are filled with sound codes. From the last block 37, the output signal is supplied to the fourth control inputs of all blocks of the registers 37 and opens the keys 39 in them, which pass one pulse U _output 75 Hz / s of block 13 of Fig. 12 /, which gives out sound codes synchronously from all blocks of the 37 registers blocks 11 _1-3 and 20 _1-3 pulse amplifiers. Nine digits codes with blocks received pulse amplifiers 27 × ¹⁰ June inputs screens 12 and 21. Flat screens 12 and 21 are identical, each comprising a number of matrix elements on resolution of 10 ^6/1000 × 1000 /. Each matrix element forms a pixel by three consecutive emissions over a frame period of 40 ms red, green and blue, each 13 ms long. The human eye at an irradiation frequency of less than 0.1 s / 100 ms / preserves the visible color image for a short time. The image of the object in a row in red, green and blue colors is sequentially superimposed in the retina one on top of another 13 ms / 0.013 s / and create the image of the object in natural colors in the human brain [3 p.79]. The repeat frequency of the color images of the three colors R, G, B on the screens is 75 Hz / 13 ms each / for a frame period of 40 ms / 25 Hz /. All elements of the screen matrix emit in parallel three 13 monochromatic color images sequentially in 13 ms: the first 13 ms is the image of the frame only in red with the brightness of the codes R, all the second 13 ms is the radiation of the image only in green with the brightness of the G codes, in the third 13 ms, the image is emitted only in blue B color with the brightness of codes B. The general view of the matrix element in Fig. 7 / above / includes an opaque body 42 in the form of a parallelepiped made of insulating material, which is also the case of the emitting cell, in which minutes at the input end by the irradiation is microlens 43 that serves as a microlens, after microlens series with each other are seven to 44 ₂ to 44 ₈ neutral mikrosvetofiltrov serving the second to eighth bits of the incoming audio codes and the three color mikrosvetofiltra 44 _R, 44 _G, 44 _B , serving only the ninth bit of incoming codes.

The first senior bit in the sound code 1,000,000 is not served by any neutral microfilter, since 100% of the radiation from the emitting cell passes when all neutral microfilter filters do not attenuate the notes of radiation after microlens 43, and it passes through the emitting cell through to the color microfilter. Nine-digit codes from pulse amplifiers have only two pulses in the codes: one in one of the second to eighth digits of the code, which controls one corresponding neutral microfilter 44 _2-8 , the second pulse is always present in the ninth digit and controls one of the three color microwaves 44 _R , 44 _G , 44 _B. The inclusion of neutral and color microfilters, respectively, of the incoming codes is illustrated in table 3.

Table 3. Incoming Code Included Neutral Microfilter Color microfilter 1-8 sound codes 9 digit color code 00000001 one 44 ₈ 44 _R or 44 _G or 44 _B 00000010 one 44 ₇ also 00000100 one 44 ₆ also 00001000 one 44 ₅ - "- 00010000 one 44 ₄ - "- 00100000 one 44 ₃ - "- 01000000 one 44 ₃ - "- 10,000,000 one 44 ₁ missing 44 _R or 44 _G or 44 _B

, микропьезоэлементы цветных микросветофильтров 45_R, 45_G, 45B срабатывают за период по одному разу.Each neutral and color microfilter is attached to the free / second / end of its micro-piezoelectric element 45 _2-8 and 45 _R , 45 _G , 45 _B , the first ends of the micro-piezoelectric elements with control inputs are rigidly fixed in the housing 42 of the matrix element. Neutral microfilter filters 44 _2-8 have emission attenuation coefficients according to the binary code principle and are given in table 4. Attenuation coefficients of color microfilter filters should be minimal and close in size to each other. For a frame period of 40 ms, the micro-piezoelectric elements 45 _{2-8 are} triggered three times for a duration of 13 ms

, micro-piezoelectric elements of color micro-filters 45 _R , 45 _G , 45B are triggered once per period.

Table 4. neutral microfilter 44 ₁ 44 ₂ 44 ₃ 44 ₄ 44 ₅ 44 ₆ 44 ₇ 44 ₈ attenuation coefficient - 0.5 0.75 0.875 0.937 0.968 0.984, 0,992 % radiation pass one hundred% fifty% 25% 12.5 16.25% 3.12% 1,56 0.78 filter density - 2 ^x 4 ^x 8 ^x 16 ^x 32 ^x 64 ^x 128 ^x

The principle of operation of the emitting cell in Fig. 8 shows the moment when the cell emits blue radiation B with a brightness code 000100001: a neutral microfilter 44 ₄ is passed into the radiation flux, which transmits 12.5% of the radiation, respectively, of the sound code 00010000, then the flow is colored blue with a color microfilter 44 _B , the control signal for entering the color filter 44 _B into the stream is the unit in the ninth category of the general code 000100001. The emitting cell is made as tiny as possible, it is one in the matrix element, there are nine in the prototype, therefore the sizes of the screens 12 and 21 at the same resolution as in the prototype will be three times smaller in length and height. The microlenses of 43 matrix elements are irradiated with white LEDs located in the corresponding quantity and in the corresponding order inside the screen body. The device contains glasses of separate fields of view (Fig. 1/), which represent a frame with ear arches, glasses windows without glasses, are interconnected by a movable vertical axis to rotate the windows relative to each other, each window has a conical hood at the end under the shape of the screen, each a two-part hood: the first part is screwed into the window, the second part is movable, extends or retracts into the first to change its length. During the first period of the frame is the concentration of sound codes in the drives 10 _1-3 and 19 _1-3 sound codes. With the end of the period of the first frame of 40 ms, codes in parallel form are issued from the drives to their blocks 1 _1-3 and 20 _{1-3 of} pulse amplifiers: the first are issued by the signal from the first output of block 13 / Fig. 1/ sound codes for color R from drives 10 ₁ and 19 ₁ into blocks 11 ₁ and 20 ₁ , respectively, from which amplified pulses up to the corresponding value and duration 13 ms are fed to the control inputs of all elements of the matrixes of screens 12 and 21, on the screens for 13 ms the image of sounds is displayed only in red R color , the second signal from the second output of block 13 issue I audio codes for the color G with drives ₁₀ February, 19 _2, blocks ₁₁ February and 20 ₂ from which amplified and duration 13 ms pulses of codes supplied to the control inputs of all elements of the matrices of both screens that within 13 msec displayed sound image only in green G, the third is the signal from the third output of block 13, the sound codes for color B blue from drives 10 ₃ and 19 ₃ into blocks 11 ₃ and 20 ₃ from which the amplified pulses of the codes lasting 13 ms are fed to the control inputs of all elements of the matrixes of the screens 12 and 21, they are displayed for 13 ms image only in blue. As a result of overlaying the colors of the same frame onto the retina, the viewer sees the image of sounds on screens in natural colors, and through glasses 4 he perceives them in a three-dimensional form. Block 13 keys / 3 / includes the first 34, second 35, third 36 keys, the signal inputs of the keys are combined and connected to the third output of the divider 2 frequency 75 Hz / 1 /, the control input of the block 13 keys is the first control input U _OT the first key 34 connected to the output 1/1/25 Hz frequency divider 2. The key output 34 is connected to the third control input of the drive 10 ₁ sound codes in the first channel / Fig. 1/ and to the third control input of the drive 19 ₁ sound codes of the second channel and is connected in parallel to its second control input U _s and to the first control input U _from the second switch 35, whose output is connected to the third control input of accumulator ₁₀ February audio codes in the first channel and the third control input of accumulator ₁₉ February audio codes in the second passageway and connected in parallel to its second control input U _of the first and at U ravlyaetsya entry _{from the} key 36, whose output is connected to the third control input of accumulator ₁₀ March audio codes in the first channel and the third control input of accumulator ₁₉ March and the second channel is connected parallel to its second control input U _s. With the arrival of the leading edge pulse _from U 25 Hz in unit 13 in the audio code keys drives followed with a frequency of 75 Hz three signals U _vyd.

The operation of the device, figure 1, 2, 7.

The inputs of the preamplifiers 5 and 14 receive stereo signals of sounds 3v1 and 3v2, which, after corresponding amplification, are fed to the inputs of blocks 6, 15 of the bandpass filters of the frequency converter, which extract signals from the first and third outputs of blocks 6, 15 of the three audio frequency ranges, respectively, of table 1, which are detected in blocks 7 and 18, and enter into their ADCs 8 _1-3 and 17 _1-3 , issuing eight-bit codes of sounds, arriving at their “binary code - brightness code” converters, and 9 _1-3 and 18 _1-3 , eight-bit codes are received to their drives 10 _1-3 and 19 _1-3 . During the first period of the frame, 40 ms of sneakers are concentrated in the storage of sound codes. At the end of the first period from block 13, three _Uout signals with a frequency of 75 Hz follow, issuing sound codes for color R from blocks 10 ₁ and 19 _{1 with} sound intervals for blocks R, sound codes for color G and from blocks from blocks 10 ₂ and 19 ₂ 10 ₃ and 19 ₃ for color B blue in blocks 11 _1-3 and 20 _1-3 , respectively, where the pulses are formed of the corresponding amplitude and duration of 13 ms and are supplied by control signals to the matrix elements of the screens 12, 21, the radiation from the matrix elements is generated on two screens color images of sounds that the viewer observes through glasses of 4 separate fields of view: left r al from the screen 12, the right eye from the screen 21. Fine tuning the windows 4 points added to steer the windows and changing the length of blends. Correspondingly, by the color and temporal change of two color images of sound signals on two screens 12 and 21, the brain of the viewer perceives the color display of sound signals also three-dimensional.

The proposed device is suitable for wide individual use in addition to household sound reproducing devices and sound reproduction equipment, can be a significant color complement when playing music in concert halls when equipped with screens, and will not be useless in the work and training of professional musicians.

Used sources

1. RF patent No. 2438747 C1, cl. A63J 17/00, G10L 21/06, bull. No 1 on 01/10/12

2. B.N. Begunov, N.P. Zakaznov, Theory of optical systems, M., 1973, p.22.

3. G.I. Ashkenazi. Color in nature and technology. M., 4th ed., 1985, 4th ed., 1985, p. 79.

4. A.F. Plonsky, V.I. Thearo. Piezoelectronics. M., 1979, p. 26, 27.

Claims (1)

A volumetric color display device for stereo audio signals containing a series-connected clock generator and a frequency divider, two identical channels, each of which contains a series-connected pre-amplifier, the input of which is one of the device’s two inputs, an audio bandpass filter (AF), a detector unit , the input of each detector is connected to the corresponding output of the bandpass filter block ЗЧ, the corresponding number of analog-to-digital converters (ADC), the input azhdogo ADC is connected to a corresponding output of the detector unit, control inputs U _d ADCs are combined and connected to the second input of the frequency divider includes a corresponding number of drives codes, each of which has the first to eighth data inputs, the same name first and second control inputs of the code disk drives are combined and connected to the first and second outputs of the frequency divider, includes the corresponding number of blocks of pulse amplifiers, each of which contains pulse amplifiers according to the number of outputs of the code store, the inputs of the pulse amplifier blocks are connected to the corresponding outputs of their code storage device, the first channel includes a fixed flat panel screen, the second channel includes a right movable flat panel screen, both screens are placed in a frame, the lower part of which under the right screen has support rollers for moving the right screen to the left and to the right, the right and left flat-panel screens are identical, each contains a matrix of elements according to the number of screen resolutions 10 ⁶ (1000 × 1000), matrix elements are connected to the outputs of the pulse blocks of the amplifiers of their channel, the matrices are irradiated with superbright white-light emitting diodes placed in the appropriate quantity and in the corresponding order on the back inner side of the screen housing, the emitting cell located in the element housing contains a microlens on the irradiation side, after the microlens there is an appropriate number of neutral microfilter filters, attached to their micropiezoelements, the first ends of which with the control input are rigidly fixed in the element housing, to the second free Neutral microfilter filters are attached to their ends, each with a corresponding absorption coefficient of radiation from the irradiation flux, the values of which correspond to the binary code principle, the microfilter filters are arranged sequentially one after another, the device contains glasses with separate fields of view, representing a frame with ear arches, windows of glasses without glasses, between each other movably connected by a vertical axis, each window has a conical hood at the end under the shape of the screen, two-part hoods: the first part is screwed into the glasses window, the other part is movable, extends and retracts into the first, changing the length of the hood, the code stores are identical, each contains register blocks by the number of lines (1000) in the screen, the information inputs are the bit-first-eighth information inputs of the register blocks, the control inputs are: the first - first control input U _{to the} (25 Hz) of the first register unit, the second - the combined second control inputs U _d (25 MHz) register blocks, the third - the combined third control inputs U _vyd register blocks, the fourth - combined These are the fourth control inputs of the register blocks, the outputs of the code storage device are the parallel outputs of all 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 block of registers is connected in parallel to the fourth control inputs of all register blocks, register blocks identical, each contains the first and second keys, a pulse distributor and eight registers, each of a thousand bits by the number of samples in a row, the bitwise combined third inputs of the bits of eight registers are the first to eighth information inputs of the register block, the control inputs of which are: the first is the first control input U _{from the} first key, the second is the signal input U _{d of the} first key, and the third is the signal input of the second key U _output , fourth - the first control input U _{from the} second key, the output of the first key is connected to the input of the pulse distributor, the outputs of which are sequentially, starting from the first, connected to the first (clock) inputs of the bits of the parallels allel eight registers, the latter thousandth, the pulse distributor output connected to the second control input U _of the first key and a first control output register unit connected to the first control input of the next register block, the second switch output is connected parallel to the second inputs of bits eight registers and to the second control input of the second key, the outputs of the block of registers are the parallel outputs of all bits of eight registers, characterized in that in each channel of the device three pre Browser “binary code - brightness code”, in each channel the block of bandpass filters of the RF is made of three active bandpass filters of the RF, the block of detectors is made of three amplitude detectors, the input of each of which is connected to the output of its active bandpass filter of the RF, the outputs of three amplitude detectors are the first to third outputs of the detector block, to each of which an ADC input is connected, the first to eighth outputs of each ADC are connected respectively to the first to eighth inputs of its converter “binary code - brightness code”, to zhdy channel comprises three drive codes, information first to eighth inputs which are connected to the first-eighth outputs its drive "binary code - brightness code", each storage code has 9 × ¹⁰ June O (3 × 3 × 10 ⁶⁾ which are connected to as many inputs of the corresponding block of pulse amplifiers, and the outputs of three blocks of pulse amplifiers 27 × 10 ⁶ (3 × 9 × 10 ⁶ ) are connected to the same inputs of the flat-panel screen of their channel, the binary-to-brightness-code converters are identical, each contains an opaque case , in to eight keys are arranged according to the number of bits of the sound code, it contains a light pulsed emitter representing a matrix of eight white pulsed light-emitting diodes fastened in the corresponding housing, the inputs of the first to eighth pulsed LEDs are connected to the outputs of the first to eighth keys, the first control inputs U _of which they are the first to eighth information inputs of the binary-to-luminance code converter and are connected to the outputs of the first to eighth digits of their ADC, the signal inputs of eight and keys are combined and are controlling the inverter input connected to the second output of the 25 MHz frequency divider, each switch output is connected to its second control output U _of each pulse the LED on the emission side has a neutral density filter with a coefficient of radiation attenuation weight respectively served code discharge them on the principle of binary code, the converter “binary code - brightness code” contains the first internal opaque housing, in the upper part of which is attached a lens, an optical the axis of which coincides with the optical axis of the light emitter, along the optical axis of the lens and at an angle of 45 ° to it are arranged sequentially one after another at an appropriate distance and eight semi-transparent micromirrors of identical size are rigidly fixed, each of which has a beam splitting coating, corresponding to the binary principle the ratio of the reflected radiation to the transmitted to the next translucent micromirror as 1: 0.5, on the side of the body to which the translucent micro-mirrors, eight corresponding photodetectors receiving reflected radiation are located, the “binary code - brightness code” converter includes a second internal opaque housing in which the first to eighth pulse amplifiers and the first to ninth keys are located, the inputs of eight pulse amplifiers are connected to the outputs of the corresponding photodetectors , the outputs of the first to seventh pulse amplifiers are connected to the same first control input U _{from the} same key and to a second control input U _s of Previous th numbering key output eighth pulse amplifier connected in parallel to a first control input U _{from the} eighth and ninth key signal of the ninth key input is connected to the control input of the inverter (25 MHz), and its output is connected in parallel to the signal inputs of the first to eighth key and its second control input U _s, the outputs of the first to eighth keys are informative converter outputs "binary code - the code brightness" bitwise combined first to eighth data inputs of register blocks odklyuchayut octet sound codes and are the first to eight data inputs of each drive codes and connected to the first-eighth outputs of the associated converter "binary code - brightness code", the ninth data inputs of the register units are combined and connected to the second control input U _d (25 MHz) drive codes, supplying the color code signal in the ninth category, together with the first to eighth bits of the sound code in the register blocks of code stores, the ninth register out of a thousand bits is entered into each register block poisons first inputs of the ninth bits of the register are connected in series to 1-1000 outputs pulse distributor, the second inputs of the ninth bits of the register are connected in parallel to the output of the second switch U _vyd register block, the third inputs of the ninth register bits are combined and the ninth data input registers in each unit, the device introduced a key block containing the first, second and third keys, the signal inputs of which are combined and connected to the third output of a 75 Hz frequency divider, the control input of the key block is the first control input U _{from the} first key is connected to the first output of the 25 Hz frequency divider, the output of the first key is the first output of the key block and connected to the third control inputs in the first drive codes of the first and second channels and connected in parallel to its second control input U _s and to the first control input U _{from the} second key, the output of which is connected to the third control inputs of the second code stores in the first and second channels and is parallelly connected to its second control input and to the first at the control input U _{from the} third key, the output of which is connected in parallel to the third control inputs of the third code stores in the first and second channels and parallel to its second control input U _s , the matrix elements in both flat-panel screens are identical, each matrix element contains an opaque case in the form a parallelepiped made of an insulating material in which one emitting cell is placed, producing three radiations of three colors, red, green, and blue, sequentially during the frame period after the irradiated microlenses are arranged sequentially from the seventh to the first neutral microfilter with attenuation coefficients of the radiation flux, respectively, the weights of the second to eighth bits of binary codes and three color microfilter of three primary colors R, G, B, dyeing the radiation at the output of the matrix element, neutral microfilter serve discharges of sound codes from the second to the eighth, arriving three times during the period, to the control inputs of the corresponding micropiezoelectric elements, colored microsvetophones The filters serve only one ninth digit of the codes and are triggered once each frame period.

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