RU2168286C1 - Digital tv set - Google Patents

Abstract

FIELD: radio communication equipment, applicable as a color television receiver in analog and digital television systems. SUBSTANCE: the digital TV set has a radio channel unit, line scanning unit, frame scanning unit, chromaticity unit, the first and second piezodeflectors with reflectors on the end, lusterless screen, three similar chromaticity beam control channels, each comprising series-connected analog-to-digital converters and the first of pulse amplifiers, pulse generator and a key, introduced is an intensity modulation unit made as a component of the first and second radiators, each having the respective number of light-emitting diodes of the respective colors, and an optical system, introduced in each chromacity control unit are a delay elements unit and the second unit of pulse amplifiers, the outputs of the units of pulse amplifiers of the three channel are connected to the respective inputs of the intensity modulation unit. The beam from the first radiator performs scanning of the raster line, the beam from the second radiator repeats it once again, which increases the average screen brightness by two times. EFFECT: enhanced average brightness of image on the screen due to enhanced brightness of the resolving picture element and repeated sweep of each line. 2 dwg, 1 tbl

Description

 The invention relates to radio communications technology and can be used as a color television receiver in analog and digital television systems.

The prototype adopted a color TV [1] containing a radio channel unit consisting of a series-connected channel selector, an intermediate frequency amplifier (UCHI), a video detector, an emitter follower, a clock selector, an automatic frequency and phase adjustment block (AFCF), and a master oscillator, an automatic frequency adjustment block a local oscillator and an AGC, a sound channel, a line scan unit as part of a preamplifier and output stage, a frame scan unit as part of a master oscillator , a preamplifier, an output stage, a back-up pulse generator and a blanking pulse generator, a color block consisting of a series-connected luminance channel and a matrix, three output video amplifiers of the primary colors R, G, B, a series-connected color signal amplifier and a block of color signal detectors, block color synchronization and a blanking pulse amplifier, three identical color beam control channels, each of which contains ADCs connected in series, a block of pulse amplifiers lei and the emitter, an optical system fixed mirror, the first pezodeflektor reflector at the end of performing progressive scan, the second pezodeflektor reflector at the end of performing the vertical scan of the beam, a matte screen, a pulse generator and a key. Amplified video signals of the primary colors are fed to the inputs of their ADCs, converted to 8-bit codes, which enter the blocks of pulse amplifiers. Signals from pulsed amplifiers turn on the LEDs in the emitters, and at the output of the three optical systems, colored beams modulated in brightness appear. The radiation of the three rays is mixed on the mirror and fed to the reflector of the first piezoelectric deflector, from it to the reflector of the second piezoelectric deflector, from it to the matte screen. The maximum brightness luminous element scanning on the screen without losses on the projection 1788 cd / m ^2, in view of losses when projected in 50% of 894 cd / m ^2. The disadvantage of the prototype: due to the short-term radiation pulse (74 ns) and the lack of afterglow of the screen, the average brightness of the image on the matte screen over the frame period (40 ms) will be small, and possibly insufficient to observe the image.

 The aim of the invention is to increase the average brightness of the image on the screen.

The goal is achieved by repeating the sweep of each line of the raster and increasing the strength of the radiation flux of the emitters. The technical result is to increase the brightness of the scanning element on the screen in 8022-fold (7,171,875: 894 cd / m ²⁾ and a doubling of the duration of the radiation due to re-scan each of the raster lines (74 x 2 ns).

 The essence of the invention is that in a digital TV containing a radio channel unit, a horizontal scanning unit, a frame scanning unit, a color block, the first and second piezoelectric reflectors with end reflectors, a matte screen, three identical color beam control channels, each of which includes connected in series ADC and the first block of pulse amplifiers, a pulse generator and a key, a brightness modulation block is introduced, made up of the first and second emitters containing the corresponding number of LEDs colors, and an optical system, and each beam chromaticity control channel elements delays introduced unit and a second unit pulsed amplifiers, the outputs of the first and second blocks of three channels of pulse amplifiers are connected to respective inputs of the luminance modulation unit.

 A block diagram of a digital television is shown in FIG. 1; luminance modulation unit and emitter - in FIG. 2.

 A digital TV (Fig. 1) includes a radio channel unit consisting of a series 1 channel selector, an intermediate frequency amplifier 2, a video detector 3, an emitter follower 4, a clock selector 5, an automatic frequency and phase adjustment unit 6, and a horizontal oscillator 7, block 8 automatic frequency control of the local oscillator and the automatic gain control unit 9, the horizontal scanning unit as part of the preliminary amplifier 10 and the output stage 11, the vertical scanning unit as a part of separately connected master oscillator 12 frame scan, pre-amplifier 13, output stage 14 and generator 15 pulsation damping pulses, and generator 16 pulses, a color block as a part of a series-connected channel 17 brightness and matrix 18, the three outputs of which are connected to the inputs of three output video amplifiers 19, 20, 21 primary colors, series-connected amplifier 22 of color signals and block 23 of color signal detectors, block 24 of color synchronization and amplifier 25 of the damping pulses, channel 26 sound support, three identical color beam control channels, the first one contains ADC 27, the first block of pulse amplifiers 28, the block 29 of delay elements and the second block 30 of pulse amplifiers, the second channel contains the ADC 31, the first block of 32 pulse amplifiers, block of 33 delay elements and the second block 34 of pulse amplifiers, the third channel contains the ADC 35, the first block 36 of pulse amplifiers, the block 37 of the delay elements and the second block 38 of the pulse amplifiers, includes a block 39 of brightness modulation, the first piezoelectric reflector 40 with a reflector at the end e, performing a line scan of the beam, a second piezoelectric deflector 41 with a reflector at the end, performing a frame scan of the beam, an opaque screen 42, serially connected pulse generator 43 and a key 44, the output of which is connected to the control inputs of three ADCs. Block 39 brightness modulation is made up of the first 45 and second 46 emitters and the optical system 47 (from the collimator and lens).

The selector 1 channels amplifies and converts the full DTV signal into an intermediate frequency of the image and sound signals. The amplifier 2 UCHI amplifies the signal to the level necessary for the normal operation of the video detector 3. The emitter follower 4 matches the path of the radio channel with subsequent stages. From the output of the emitter follower 4, the DTV signal is fed to the clock selector 5, to the luminance channel 17 of the color block and to the amplifier 22 of the color signals. The sync selector 5 extracts the horizontal and frame sync pulses from the full DTV signal and generates strobe pulses for the color block. The master oscillator 7 generates horizontal control pulses for block 10 of the pre-amplifier. The master oscillator 12 generates frame control pulses for the output stage 14, the generator 15 generates the duration of the pulse blanking backward. The output stages 11 and 14 are loaded on the piezoelectric elements of the piezoelectric deflectors 40 and 41, which are characterized by small energy losses, and generates voltage control signals for them. In the color block, demodulation of the color signals is performed, the voltage of the primary colors is formed, the contrast, saturation and brightness of the image are adjusted. Amplifier 22 extracts frequency subcarriers of color signals and amplifies them in the channels of direct and delayed signals. Block 23 detects color difference signals that enter the matrix 18. Color synchronization block 24 generates half-line frequency control pulses for switching the branches of the electronic switch. As a result, at the output of the detector unit 23, two color-difference signals E _RY and E _BY are generated, which enter the matrix 18. In the luminance channel 17, the luminance signal is amplified and the black level is fixed. The matrix 18 performs the matrixing of color difference signals, generates a green color difference signal, and adds three color difference signals with a luminance signal. From the output of the matrix 18, the primary color signals are fed to the output video amplifiers 19, 20, 21, amplified in them to the values necessary for the operation of the ADC 27, 31, 35. The ADC converts the video signals of the primary colors into 8-bit codes. The first blocks 28, 32, 36 of pulse amplifiers form signals from the pulses of the code for energizing the LEDs in the first emitter 45. Blocks 29, 33, 37 of the delay elements contain eight delay elements (according to the number of bits in the code) that delay the code pulses for the duration line scan period 64 μs. The second blocks 30, 34, 38 of the pulse amplifiers form signals from the delayed pulses of the code for energizing the light emitting diodes in the second emitter 46, which performs repeated irradiation of the raster line. The blocks of pulse amplifiers are identical and each contains eight (by the number of bits) amplifiers. As blocks of pulse amplifiers, microcircuits of amplifier-shapers 533AP6 are used [2, p. 128] with a response time of 18 ns. The first and second emitters 45, 46 are identical and each includes 36 LEDs consisting of 12 red, 12 green and 12 blue, laid (Fig. 2), one in the center, the rest around it. When the diameter of the LED is 5 mm [5, p. 71] the emitter has a diameter of up to 30 mm. The radiation plane of both emitters is located in the rear focal plane of the optical system 47. Vertically, the first emitter 45 is located above the second emitter 46. The optical system 47 performs additive mixing of the three color emissions of the LEDs of each individual emitter, focusing the radiation of each emitter into its resolving light element on the reflector of the first piezoelectric deflector 40 with the distance between them in one line. The optical system 47 inverts the images of the emitters in a vertical plane on the reflector of the first piezoelectric deflector 40, therefore, in the vertical plane the first emitter 45 is located above the second emitter 46, and on the reflector of the first piezoelectric deflector 40 the radiation of the second emitter 46 is above, the radiation of the first emitter 45 is lower. On the frosted screen, the image is first scanned from the first emitter 45, followed by the image from the second emitter 46. The free end face with the vertically arranged reflector of the first piezoelectric deflector 40 is located in the front focal plane of the optical system 47 and performs a horizontal scan of two beams on the horizontally located reflector of the second piezoelectric deflector 41 performing a personnel scan of two rays on the opaque screen 42 located opposite it. With a resolution element of 0.02x0.02 mm on the reflector of the second piezoelectric deflector 41, its reflector has a length of 720 _counts • 0.02 mm = 14.4 mm. Piezoelectric deflectors are bimorph face piezoelectric elements [3, p. 192; 4, p. 56]. The pulse generator 43 generates sampling pulses for the ADCs 27, 31, 35 and is a frequency multiplier of the master oscillator by 864: 15625 Hz • 864 = 13.5 MHz.

 It can be made of three self-propelled pulse distributors that perform multiplication by 12, 9 and 8 [6, p. 274].

где в числителе - суммарная сила света от излучателя, причем принято, что светодиоды всех цветов имеют ту же силу света, что светодиоды синего цвета, т.е. 300 мкд;
0,5•10^-6 м² - площадь элемента разрешения на экране 42;

коэффициенты двоичного кода с 4 по 8 разряды (см. таблицу).Key 44 skips sampling pulses during the forward horizontal scan. The blanking pulse amplifier 25 receives the flyback pulses of the horizontal and vertical scans and generates pulses at the output that are supplied to the control input of the key 44, closing it for the duration of the reverse pulses. ADCs convert video signals into 8-bit codes with a sampling frequency of 13.5 MHz. To obtain a sufficient radiation flux, HLMP series LEDs manufactured by the Hewlett-Packard company are used [5, p. 71]: red HLMP-ALOO with a luminous intensity of 400 mcd at a current of 20 mA, green LEDs of HLMP-AMOO radiation with a wavelength of 0.526 μm and a luminous intensity of 800 mcd at a current of 20 mA, blue HLMP-ABOO with a wavelength of 0.475 microns and luminous intensity 300 mcd [5 c. 71] at a current of 20 mA. The beam is modulated by the brightness of each color by switching on the radiation of the corresponding number of LEDs of the same color with the presence of corresponding attenuating filters according to the weight of the discharge in the code (table). With a resolution element on the screen 42 of 0.5 mm ² (0.7 x 0.7 mm), the maximum brightness of the expanding glow element on the screen is

where in the numerator is the total light intensity from the emitter, and it is assumed that the LEDs of all colors have the same light intensity as the blue LEDs, i.e. 300 mcd;
0,5 • 10 ^-6 m ² - the area of the resolution element on the screen 42;

binary code coefficients from 4 to 8 digits (see table).

Equalization of the light intensity of red, green LEDs with blue is carried out by installing in their exit pupils additionally appropriate attenuating light filters. The radiation loss during projection onto the screen is accepted at 50%, while the brightness of the resolution element on the screen is 7171875 cd / m ² . The average brightness of the image increases at 16044, which consists of an increase in 8022 times the brightness of the element on the screen (7171875: 894) and a double increase in exposure due to re-scanning the line.

 The work of a digital TV.

 The high-frequency signal received by the antenna from the selector 1 of the channels enters the OCHI 2, from it to the video detector 3, the sound signal is separated into the sound channel 26, and the DTV signal through the emitter follower 4 enters the clock selector 5, into the brightness channel 17 and into the amplifier 22 color signals. From the output of the detector unit 23, two color-difference signals enter the matrix 18, from which they are fed to the inputs of their ADCs, converted into codes that enter the blocks of pulse amplifiers 28, 32, 36 and the blocks of delay elements 29, 33, 37. Signals from the first blocks of pulse amplifiers are fed to the inputs of the first emitter 45, the signals from the second blocks of pulse amplifiers are fed to the inputs of the second emitter 46. The radiation from the first emitter 45 by the optical system 47 is focused on the reflector of the first piezoelectric deflector 40, which produces the beam of this beam on the reflector, the second piezoelectric deflector 41, which scans the image with the beam of the first emitter 45 on the screen 42. The radiation from the second emitter 46 of the optical system 47 focuses on the reflector of the first piezoelectric deflector 40 above the line from the light spot of the beam from the first emitter 45. The piezoelectric deflector 40 also produces a line scan of the beam from the second emitter 46 on the reflector of the second piezoelectric deflector 41. The beam from the second emitter 46 re-scans the same line that was deployed in front of it with a beam from the first emitter 45 on the screen 42. Thus, the reflector of the second piezoelectric deflector 41 reproduces the color image on the matte screen 42 simultaneously with two beams.

 The inventive digital TV can be used as a television receiver in both analog and digital television systems.

Sources of information
1. Patent N 2099901 "Color TV", cl. H 04 N 9/12, bull. N 35, 1997 - prototype.

 2. Digital integrated circuits. - Minsk, 1991, p. 128.

 3. Handbook of laser technology / Ed. Bayborodina, Kiev, 1978, p. 192, 194.

 4. Calculation of elements of laser scanning systems, EV Dneprovsky et al. - Minsk, 1986, p. 56, tab. 2.3.

 5. Radio, N 7, 1998, p. 71.

 6. V.A. Ilyin. Remote control and telemetry, M., 1982, p. 274.1

Claims (1)

A digital TV, including a radio channel unit, containing a series-connected channel selector, an intermediate frequency amplifier, a video detector, an emitter follower, a clock selector, and an automatic frequency control unit. phases and a horizontal line master, a local oscillator automatic gain control unit and an automatic gain control unit, a horizontal line block containing a preamplifier connected in series, the input of which is connected to the output of a horizontal line master in the radio channel unit, and an output stage, a vertical block serially connected frame scanning master generator, the input of which is connected to the corresponding output of the clock selector in the block Iokanal, a preamplifier, an output stage and a blanking pulse generator, and a reverse pulse generator, the input and output of which is connected to the corresponding input and output of the output stage, a color block containing a luminance channel and a matrix connected in series, three outputs of which are connected to the inputs of three output primary color video amplifiers, a color signal amplifier and a color signal detector unit connected in series, the inputs of the luminance channel and the color signal amplifier being connected s to the output of the emitter follower of the radio channel block, the output of the block of color signal detectors is connected to the second input of the matrix, the color block
synchronization, the first input of which is connected to the corresponding output of the clock selector, the second input is to the output of the blanking pulse generator in the frame scan unit, the third input is to the second output of the color signal amplifier and the output is to the second input of the color signal detector block, and the blanking amplifier, the first input of which is connected to the output of the blanking pulse generator in the vertical scanning unit, the second input is connected to the second output of the output stage of the horizontal scanning unit, and containing the sound channel the input, which is connected to the output of the video detector, the first and second piezoelectric deflectors with reflectors at the end, a matte screen located opposite the reflector of the second piezoelectric deflector, three identical color beam control channels, each of which includes ADC and the first block of pulse amplifiers connected in series and connected in series a pulse generator and a key, the input of the first piezoelectric deflector connected to the first output of the output stage horizontal line, the input of the second piezoelectric deflector to the second output at the output stage of the vertical scan and its reflector is optically connected to the reflector of the first piezoelectric deflector, the input of the pulse generator is connected to the output of the master oscillator of the horizontal scan in the radio channel block, the output of the key is connected in parallel to the control inputs of the three ADCs whose inputs are connected to the outputs of the corresponding output video amplifiers of the primary colors in color block, the control input of the key is connected to the output of the blanking pulse amplifier in the color block, characterized in that a brightness m a radiation containing the first and second emitters, each of which contains a corresponding number of LEDs of corresponding colors, and an optical system, the first emitter being located vertically above the second and the emitting plane of both emitters is located in the rear focal plane of the optical system, in which the reflector is located the first piezoelectric deflector, radiating sides of the first and second emitters through the optical system, the reflectors of the first and second piezoelectric deflectors optically with They are connected to the screen of the matte screen, a series of delay elements and a second block of pulse amplifiers are introduced into each channel of the color beam control, the inputs of the block of delay elements being connected to the corresponding inputs of the first block of pulse amplifiers, and the outputs of the first and second blocks of pulse amplifiers of three color beam control channels connected to the corresponding inputs of the brightness modulation unit.

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