RU2013880C1 - Tv signals receiver - Google Patents

Abstract

FIELD: TV engineering. SUBSTANCE: device has parabolic aerial 1, aerial rotating unit 2, remote control board 3, polarizers unit 4, superhigh frequency amplifier 5, remote control receiver 6, the first and the second frequency converters 7 and 12, the first and the second heterodynes 8, 13, solving unit 9, the first intermediate frequency amplifier 10, matching unit 11, unit for controlling rotating unit of the aerial, the second intermediate frequency amplifier 15, unit 16 for separating signal of sound accompaniment, sound accompaniment separating unit generator 17. Functional capabilities of the receiver may be widened due to automation of processes of setting and tuning parameters of channel of satellite television. EFFECT: widened functional capabilities. 2 dwg

Description

 The invention relates to a technique for receiving television signals and can be used for receiving satellite television programs for individual and collective use, as well as in satellite telephone systems with multiple access using different satellites.

 A television is known, which is connected with an external organ equipped with a sensor - a receiver of signals received using a system oriented to a geostationary satellite, having built-in motors for changing the position of the antenna using a command transmitted by a remote control unit.

 This device uses a remote control to adjust the position of the antenna, but there is no adjustment of the position of the antenna, the need for which is due to the fact that the position of the satellite can change over time. In addition, other parameters may change over time, for example, the frequency of the received signal, the type of video signal, the type of polarization. AFCs of the first and second local oscillators monitor the change in the corresponding frequencies. But the range of the AFC is not able to cover the entire frequency spectrum of the received signal.

 The closest technical solution to the proposed is the receiving station of satellite television broadcasting. It contains a parabolic antenna, a block of polarizers, an microwave amplifier, a first frequency converter, a first local oscillator, a first intermediate frequency amplifier, a second frequency converter, a second local oscillator, a second intermediate frequency amplifier, a sound separation unit, a computer (extreme machine or solver), a rotatable antenna unit, a control unit for the rotation of the antenna, and the output of the parabolic antenna is connected through the block of polarizers and the microwave amplifier from the first the input of the first frequency converter, the second input of which is connected to the output of the first local oscillator, and the output of the first frequency converter is connected through an amplifier of the first intermediate frequency to the first input of the second frequency converter, the second input of which is connected to the output of the second local oscillator, the output of the second frequency converter is connected to the input of the amplifier a second intermediate frequency, the output of which is simultaneously the first output of the device and connected to the first input of the audio accompaniment allocation unit, the input of which is connected to the output of the sound generator, the second output of the amplifier of the second intermediate frequency is connected to the input of the computer, the output of which is connected to the input of the antenna rotation control unit, the first and second outputs of which are connected to the first and second inputs of the antenna rotary unit, the mechanical output of which is connected to parabolic antenna, the output of the audio accompaniment separation unit is the second output of the device.

 This device has the ability to periodically monitor the position of the antenna and, if necessary, adjust the position of the antenna.

 Television broadcasting from satellites is practically carried out in the entire frequency range from 10.7 to 12.75 GHz. To simplify the organization of the selection of one desired channel at earth stations, in addition to frequency separation, polarization and spatial separation are used. When radiation from satellites can be applied circular (left or right) polarization, as well as vertical or horizontal plane polarization, i.e. four types of polarization of the emitted signal.

 Spatial selectivity is realized when transmitting signals of the same frequency and the same polarization from two different geostationary satellites with sufficient diversity in longitude.

 The subcarriers of the sound frequency of television programs vary within 5.5. . . 8.2 MHz Various pre-emphasis circuits are used in the image channels.

 Therefore, the transition from one channel to another (that is, the transition from receiving one television program to another) necessitates one or more switches: changing the direction of the axis of the antenna pattern of the receiving device (switching the position of the antenna); change of polarization of the received signal; changing the tuning frequency of the receiver local oscillator, which selects the desired channel (usually this is the restructuring of the second local oscillator); changing the local oscillator frequency of the audio signal isolation device (sound generator); change of the image signal of the reconstructing circuit connected at the output of the demodulator.

 To switch from receiving one channel to another, the user must enter into the channel selection device not only the number of the desired channel, but also make the necessary switches.

 The prototype uses automatic antenna position adjustment. The remaining switches are manual.

 The aim of the invention is to improve the quality of the received signal by automating the installation and adjustment of the parameters of the satellite TV channel.

 This goal is achieved by the fact that in the device for receiving television signals containing a parabolic antenna connected to the block of polarizers, the output of which is connected to the input of the microwave amplifier, connected in series with the first frequency converter, the amplifier of the first intermediate frequency, the second frequency converter, the second frequency converter and an amplifier of the second intermediate frequency, the output of which is connected to the first input of the computer, the second inputs of the first and second converters h the frequencies are connected to the outputs of the first and second local oscillators, respectively, the second output of the amplifier of the second intermediate frequency is connected to the input of the audio accompaniment allocation unit and is the first output of the device, the first output of the audio accompaniment allocation unit is the second output of the device, and the second output is the input of the calculator, the input of the unit the sound accompaniment is connected to the output of the sound generator, the output of the antenna rotation control unit is connected to the antenna rotary unit, the output of which is mechanically connected to a parabolic antenna, the output of the computer is connected to the input of the antenna rotation control unit, an additional remote control is introduced, the output of which is connected to a remote control receiver, the output of which is connected to the fourth input of the computer, the second output of which is connected to the input of the interface unit, the first and second outputs which are connected to the inputs of the first and second local oscillators, the third output is connected to the input of the sound generator, and the fourth output is connected to the second input of the block of polarizers.

 In FIG. 1 is a structural diagram of a television signal receiving apparatus; in FIG. 2 shows one of the variants of the concept of the computer.

 The device contains a parabolic antenna 1, a rotary antenna unit 2, a remote control 3, a block of polarizers 4, an microwave amplifier 5, a remote control receiver 6, a first frequency converter 7, a first local oscillator 8, a calculator 9, an amplifier of the first intermediate frequency 10, a pairing unit 11, a second frequency converter 12, a second local oscillator 13, an antenna rotation control unit 14, a second intermediate frequency amplifier 15, an audio accompaniment allocation unit 16, a sound generator 17.

 The device operates as follows.

 The input signal from the satellite is received by a parabolic antenna 1, which is directed in a predetermined direction using the rotary unit of the antenna 2. This direction is set by the calculator 9, in the storage device of which data is stored on all channels of satellite television. The rotary antenna unit is controlled by the antenna rotation control unit 14. The memory of the calculator 9 also stores data on the type of polarization, on the frequency of the second local oscillator, on the frequency of the sound generator, on the number of the subband of the first local oscillator, on the number of the predistortion circuit of the image signal, on the form Signal: positive-negative. Therefore, when receiving a signal from the remote control 3 about the number of the channel selected by the user, the calculator 9 provides all the data on which the device is prepared for operation. In this case, the rotary unit of the antenna 2 is set in motion until the antenna 1 occupies the specified position, the type of polarizer is selected, the subband number of the first local oscillator is determined and, if necessary, the frequency of the second local oscillator is set to the specified value, the frequency of the sound generator is set, all switches are set to the specified position . All operations are performed automatically.

 Next, the signal received by the parabolic antenna 1 is fed through the block of polarizers 4 to the input of the first frequency converter 7, the second input of which receives a signal from the first local oscillator 8. The resulting signal of the first intermediate frequency is amplified by the amplifier of the first intermediate frequency 10 and fed to the second frequency converter 12, to the second the input of which receives a signal with a frequency of the second local oscillator. At the output of the second frequency converter 12, a resulting signal is generated with a second intermediate frequency, which, after amplification, is fed to the output of the device and to the input of the audio accompaniment extraction unit 16, the second input of which receives a signal from the sound generator 17. The resulting signal of the intermediate frequency of sound after amplification is fed to second device output.

 After the signal passes through the intermediate frequency paths, the image and sound signals are controlled by a calculator 9, which determines the average detected level of signals coming from the output of the amplifier of the first intermediate frequency 10, from the output of the amplifier of the second intermediate frequency 12 and from the output of the audio accompaniment selection unit 16. If the level of these signals corresponds to the norm, then the adjustment of the parameters is not performed.

 The verification of these signals is carried out in a certain sequence both after setting the parameters to a predetermined position, and periodically, for example, every 30 minutes.

 If one of the output parameters is not normal, then the calculator generates a tuning signal for this parameter. At the output of the interface unit or the antenna rotation control unit, mismatch signals are generated, which are fed to the adjustable element of the tested path. When monitoring the signal from the output of the amplifier of the first intermediate frequency 10, the tuning quality of the rotary unit of the antenna 2 is checked. When adjusting the position of the antenna, the mismatch signals are first generated to the rotation unit of the antenna 2 to turn on the antenna moving engine in azimuth, then the antenna moving engine in elevation is switched. Each time you change the position of the antenna, the signal quality is checked one step. This process lasts until the “Normal” signal arrives or at the end of the entire tuning cycle of this parameter. Then, the signal quality is checked by the signal level of the second intermediate frequency. If necessary, the frequency of the second local oscillator is adjusted. At the same time, at the output of the calculator 9, mismatch signals are generated that adjust the second local oscillator 13. A similar process occurs when the sound generator 17 is tuned.

 The program of work of the calculator 9 is designed in such a way that the quality of tuning the parabolic antenna 1 in azimuth is first controlled, and then in elevation. If when adjusting the angle in azimuth, the signal remains insufficient for normal reception, then the calculator generates a signal for adjusting the antenna in elevation. Thus, by varying the switching of adjustments in azimuth, elevation and signal level from the output of the amplifier of the second intermediate frequency, it is possible to achieve the required quality of the television signal.

 Since the adjustment program can be changed (this depends on the instructions recorded in the memory of calculator 9), if necessary, you can use the program to adjust the signal quality according to the level of the final signal (signal from the output of the amplifier of the second intermediate frequency 12). In this case, the calculator monitors only the level of one signal and, if necessary, sequentially generates the adjustment signals of all these elements. The quality of the sound signal is monitored at the output of the sound accompaniment extraction unit 16. If necessary, the calculator 9 generates a signal for tuning the sound generator 17.

 All units of the device can be performed on the basis of widely used domestic microcircuits. Many blocks can be performed according to known schemes.

 Units such as a parabolic antenna, a rotary antenna unit, an antenna rotation control unit, first and second converters, first and second local oscillators, amplifiers of the first and second intermediate frequencies, a sound accompaniment allocation unit, and a sound generator can be performed according to the prototype.

 The interface unit is a circuit of digital-to-analog devices, made according to the known scheme. The decoders and switches used in this unit are made on microcircuits of the K155ID1 and K176KT1 type, respectively, but can be performed on other circuits similar in function.

 The main element of the computer (solver) is the K1816 microprocessor. Communication of the microprocessor with external devices is carried out through the registers made on the MS K5804P82 (Fig. 2). The K176KT1 chip is used as a switch, and the MS K1401CA1 block of comparators is used. The ROM unit is made on the basis of read-only memory devices of the type K573RF2. In addition to the main elements, the calculator also has auxiliary elements. These include a step-by-step mode scheme. This mode is used when setting up and checking the program recorded in ROM on the K573RF2 MS. The trigger (K155TM2) and the K155LAZ MC provide a diagram for eliminating the contact bounce of the S11 toggle switch.

 When you switch the toggle switch S12, the circuit is switched to the mode of continuous extraction of commands from the ROM (DD16). The microprocessor (DD25) controls external devices through registers. The channel dialing unit includes a set of keys S1. . . S10, encoder (DD1), DD5 match circuit, DD7 inverter and DD6 trigger.

 The block for converting an analog signal to a code includes a block of switches (DD2), a block of comparators (DAI), a matching circuit (DD7), registers DD3 and DD4. The DD3 register acts as an output device of the microprocessor, and DD4 acts as an input device. Registers DD11, DD15, DD17, DD18 are buffer elements when storing information about the adjustment. The outputs of these registers are connected to the corresponding inputs of the EPROM block (low-order bits) DD17, DD19, DD20, DD22, DD23. The binary-decimal code to binary converter is implemented on the DD21, DD24 MS.

 The technical advantages of the proposed in comparison with the prototype are that when receiving various television programs, the installation and adjustment of the parameters corresponding to this channel is performed automatically without user intervention, which can significantly improve the quality of adjustment and simplify the operation of the device. No special controls are required for the user. The user selects the desired program (channel) from the remote control.

 There is an opportunity to simplify the receiving device, to reduce its size. This allows you to place the satellite receiver directly on the TV, which eliminates unnecessary modulation-demodulation and improves the quality of the received signal. In serial samples, you can significantly reduce the cost of the entire receiving device compared to the separate total cost of the TV and satellite TV receiver by combining it in one housing with the TV. Such a device will allow receiving both terrestrial television programs and satellite television programs, which makes it universal.

Claims (1)

 TELEVISION SIGNAL RECEIVER, comprising a parabolic antenna connected to polarizer blocks, the output of which is connected to an input of an microwave amplifier, connected in series with a first frequency converter, a first intermediate frequency amplifier, a second frequency converter and a second intermediate frequency amplifier, the output of which is connected to the first input the second inputs of the first and second frequency converters are connected to the outputs of the first and second local oscillators, respectively, the second output of the amplifier of the second intermediate frequency is connected to the input of the audio accompaniment allocation unit and is the first output of the device, the first output of the audio accompaniment allocation unit is the second output of the device, and the second output is with the input of the calculator, the input of the audio accompaniment allocation unit is connected to the output of the sound generator, output the antenna rotation control unit is connected to the antenna rotary unit, the output of which is mechanically connected to the parabolic antenna, the output of the computer is connected to the input of the unit control antenna rotation, characterized in that, in order to improve the quality of the received signal by automating the installation and tuning of channel parameters, a remote control is introduced, the output of which is connected to a remote control receiver, the output of which is connected to the fourth input of the computer, the second output of which is connected to the input of the interface unit, the first and second outputs of which are connected to the inputs of the first and second local oscillators, the third output is connected to the input of the sound generator, and the fourth nth output - to the second input of the block of polarizers.

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