RU2094953C1 - Displaying tv set - Google Patents

Abstract

FIELD: radio engineering, in particular, receiving TV programs in meter and decimeter bandwidth, display for home and personal computers. SUBSTANCE: device has two antenna inputs which are connected to corresponding channel selectors 2.1 and 2.2. channel selector 2.1 is connected to input of radio channel unit 2.3, which output is connected to joined inputs of selectors 2.1 and 2.2, which are connected to also to output of program selector 4. Second output of radio channel unit 2.3 is connected to input of low-frequency amplifier 1.1, which output is connected to dynamic head. Video output of unit 2.3 is connected to input of video signal interface unit 2.3, which output is connected to corresponding inputs of line scanning unit 5, frame scanning unit 7 and video amplifier 8. Outputs of frame and line scanning units 7 and 5 are connected to inputs of dynamic focusing unit 6, which output is connected to input of kinescope 10. Output of video amplifier is connected to second input of kinescope 10. Line scanning unit 5 not only generates deviation line sweeping current but also outputs high-voltage anode voltage for operations of kinescope 10, stepping-up voltage for power supply of video amplifier 8, power supply of variable capacitors 9, dynamic focusing unit 6. Voltage which has been stabilized in power supply of variable capacitors 9 is sent to program selector 4. Suppression pulse generator 11 is connected to modulator of kinescope 10. Second input of suppression pulse generator 11 is connected to output of frame scanning unit 7. Third output of suppression pulse generator 11 is connected to output of line scanning unit 5. EFFECT: increased functional capabilities. 4 dwg

Description

 The present invention relates to the field of radio engineering and may find application for receiving television programs in the range of meter and decimeter waves, as well as to work as a monitor for household and personal computers. It is also possible to use a consumer’s monitor as a television receiver when using a television signal processing unit.

 Currently, the industry produces a large number of black-and-white and color television sets, which are widely described in the technical literature. See, for example, Gedzberg Yu.M. Repair black and white portable TVs. M. Radio and communications, 1992 Sotnikov S.K. Adjustment and repair of color televisions ULPTST (I) 59/61-P. M. Radio and communications, 1984. Elyashkevich S.A. Color TVs ZUSTST. M. Radio and Communications, 1989.

 All of these household television receivers provide a resolution of 350,450 lines vertically, which makes it impossible to reproduce all the transmitted information according to the television standard (625 lines).

 Closest to the technical nature of the proposed is a television receiver ZUSST, described in the reference manual S. Elyashkevich Color TVs ZUSTST. M. Radio and Communications, 1989c. 6.7, fig. 1.1.

 In FIG. 1 is a structural diagram of this TV, where it is indicated: 1 control unit, 2 radio channel module, 3 power supply unit, 4 - program selection device, 5 picture tube demagnetization device, 6 - power supply filter, 7 connection board, 8 color module, 9 horizontal scanning module , 10 personnel scanning module, 11 picture tube, 12 - magnetostatic device, 13 deflecting system.

 The control unit 1 includes a low-frequency amplifier 1.1 and an adjustment unit 1.2. The radio channel module includes the first 2.1 and second 2.2 channel selectors, the radio channel submodule 2.3 and the synchronization submodule 2.4.

 ZUSSTT television receiver can operate in the meter and decimeter wavelength range. Radio channel module 2 is intended for the selection of broadcast television radio signals, their conversion into IF signals, the formation of PCTS and audio signals, as well as gating pulses for chrominance module 8, triggering pulses for horizontal scanning module 9 and synchronizing pulses for vertical scanning module 10. Constant voltages necessary for switching channel selectors 2.1 and 2.2 to the required wave ranges and for their settings come from the program selection device 4.

 In the color module 8, color signals are extracted from the PCTS, the direct and delayed signals are amplified, the color signals are separated, the color-difference signals are detected and amplified.

 From color module 8, the primary color signals and blanking pulses are fed to the kinescope board 11. On the kinescope board 11 are placed arresters, limiting resistors, and accelerating and focusing voltage regulators.

 The radio channel module 2 is connected to the control unit 1, which in turn is connected to the television program selection device 4.

 There is also a luminance channel in the color module. The horizontal line and frame scanning modules 10 are designed to create deflecting currents of horizontal and frame frequencies and the formation of impulse voltages necessary for the operation of dimensional stabilization devices and the device for limiting the beam current.

 The power supply module 3 comprises a network voltage rectifier, a pulse generator, a stabilization and overload protection device, and a trigger device.

 The modules are connected to the power source through the backplane 7.

 The disadvantage of such a television receiver is its low resolution (350-450 vertical lines), and, therefore, the impossibility of reproducing all the transmitted information.

 To eliminate this drawback, it is proposed to use a monitor with dynamic focusing and a television set-top box.

 A block diagram of such a device is shown in FIG. 2, where it is indicated: 1 control unit, 2 television signal processing unit, 3 power supply unit, 4 program selection selector, 5 horizontal scanning module, 6 dynamic focusing unit, 7 vertical scanning module, 8 video amplifier module, 9 varicap driver, 10 picture tube , 11 - shaper pulsation blanking rays, 12 deflecting system, 13 synchronization unit, 14 magnetostatic device.

 The control unit 1 includes a low-frequency amplifier. The television signal processing unit includes a channel meter selector 2.1, a decimeter band selector 2.2, a radio channel 2.3 submodule, and a video signal matching submodule 2.4.

 The whole device can be presented in two parts: I - a television radio and monitor II.

 The proposed device contains two antenna inputs (meter and decimeter bands) connected to the corresponding channel selectors 2.1 and 2.2. The channel selector 2.1 is connected to the input of the submodule of radio channel 2.3, one output of which is connected to the combined inputs of the selectors 2.1 and 2.2, which are also connected to the output of the program selector 4. The second output of the submodule of radio channel 2.3 is connected to the input of the low-frequency amplifier module 1.1, the output of which is connected to dynamic head. The video output of submodule 2.3 is connected to the input of the submodule for matching video signal 2.4. The output of the video signal matching submodule is connected to the corresponding inputs of the horizontal scanning module 5, the personnel scanning module 7, and the video amplifier 8. The outputs of the personnel 7 and horizontal 5 scanning modules are connected to the inputs of the dynamic focus unit 6, the output of which is connected to the input of the kinescope 10. The output of the video amplifier 8 is connected to the second input of the tube 10.

 The horizontal scanning module 5, in addition to creating a deflection current of the horizontal frequency, generates a high-voltage anode voltage for operating the kinescope 10, increasing the voltage for supplying the video amplifier module 8, the varicap driver, the dynamic focus unit 6. The voltage stabilized in the varicap driver 9 is supplied to the selector program selection of 4 television radios.

 The blanking pulse generator 11 is connected to the kinescope modulator 10. The second input of the blanking pulse generator 11 is connected to the output of the vertical scanning module 7, and the third to the output of the horizontal scanning module 5.

 The device operates as follows.

 The television signal is fed to the antenna or meter range, or decimeter. From the corresponding antenna, the signals are sent to the channel selectors 2.1 and 2.2, where they are selected. The constant voltages required to switch the channel selectors 2.1 and 2.2 come from the program selector 4.

 The output of the channel selector 2.1 is connected to the submodule of the radio channel 2.3, where the amplification of the IF image signals and interference suppression occurs. From one output of submodule 2.3, the signal enters the low-frequency amplifier module 1.1, which serves to amplify low-frequency signals from 0.2 V to a level that provides the nominal sound pressure of a dynamic emitter. From the other output of the radio channel 2.3 submodule, the signal is fed to the 2.4 video signal matching submodule, which serves to match the amplitude of the variable component and the constant component level of the standard video signal from the radio channel 2.3 submodule to the input signal for the monitor. The video signal from the output of block 2.4 is fed to the horizontal scanning module 5, to the vertical scanning module 7, and to the video amplifier 8. The horizontal and vertical scanning modules 5 and 7 create deviating currents of the horizontal and vertical frequencies, and generate pulse voltages for automatic adjustment of the frequency and phase. From the outputs of the lowercase 5 and frame 7 scan modules, the signals are sent to the dynamic focusing unit 6, which is connected to the kinescope 10 by its output. The amplified video signal from the video amplifier 8 also goes to the cathode of the kinescope 10. The kinescope 10 also receives a quenching pulse, which is generated in the former 11 according to the signals coming from the lowercase 5 and personnel scanning modules.

 The shaper of the supply voltage of the varicaps 9 generates at the output U 31 V to power the varicaps that are part of the channel selectors 2.1 and 2.2. The whole system is powered by a power source 3. Switching power supply 3 allows you to convert 220V into a constant voltage, decoupled from the stabilization source. To power the monitor, + 12V 2A is used, to power the blocks of the radio channel + 10.5V 0.3A, + 15V 0.4A to power the ULF. Almost all blocks of the proposed device are standard. Channel selectors: SK-M-24-2 and SK-D-24; the submodule of the SMRK-2, ULF radio channel is assembled on a K174 UN7 series chip, the SVP-4-10 program selection device.

 The video matching submodule is depicted in FIG. 3, it brings the output signal of the submodule of the radio channel to the input signal of the monitor in terms of the magnitude of the variable component and the level of the constant signal.

 The video amplifier is used to work with an analog signal and has a standard circuit solution.

 The reverse beam suppressor is shown in FIG. 4. It allows you to avoid reflection of the return signals of the rays on the picture tube screen when displaying a real television signal.

 The block of dynamic focusing is made according to the standard scheme for monitors such as "Electronics MS 6105".

 This unit in combination with a high-precision magnetostatic device and a special picture tube allows you to get a resolution of up to 1000 lines horizontally. This unit carries out a voltage change, which serves to focus the electron beam, depending on the deflecting currents of the horizontal and frame frequencies.

 The use of a video signal matching unit, a video amplifier, a shaper of pulsation blanking, dynamic focusing allows you to obtain a vertical resolution of 700 lines and 1000 lines horizontally, i.e., the resolution of the device is approximately 2 times higher. At the same time, the quality of the television information display is improved. Geometric and non-linear image distortions are reduced.

 In addition, when using monitor picture tubes, the mean time between failures is 5 times more than simple picture tubes (10 thousand hours versus 2 thousand hours).

Claims (1)

 A television monitor containing two antenna inputs connected to the respective channel selectors, the output of the decimeter channel selector is connected to one of the inputs of the meter channel selector, the output of the meter channel selector is connected to the input of the radio channel submodule, consisting of an intermediate image frequency amplifier and an intermediate audio frequency amplifier, the output of which is connected to the combined inputs of the channel selectors, which are connected to the output of the program selection device, the output of the interval amplifier the frequency of sound is connected to the input of the low-frequency amplifier, the output of the intermediate-frequency amplifier of the image of the submodule of the radio channel is connected to the input of the horizontal and vertical scanning unit, the kinescope of the high-precision magnetostatic device, as well as the power supply, one output of which is connected to the inputs of both channel selectors, the radio channel submodule, the device program selection, the second output is connected to the input of the low-frequency amplifier, the third output is connected to the horizontal and vertical scanning unit, kinescope, synchronization unit and, characterized in that a cascade of video signal matching is introduced, the input of which is connected to the output of the intermediate-frequency amplifier of the image of the submodule of the radio channel, a dynamic focusing unit, a shaper of pulsation blanking, and, in addition, the output of the video matching submodule is connected to the input of the horizontal and vertical scanning unit, with the input of the video amplifier, the output of which is connected to the kinescope, the first output of the horizontal and vertical scanning unit is connected to the input of the reverse blanking pulse shaper rays, the output of which is connected to the kinescope, the second output of the horizontal and vertical scanning unit is connected to the input of the dynamic focusing unit, the output of which is also connected to the kinescope.

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