SU1125772A1 - Device for forming correcting signal of television transmitter - Google Patents

Abstract

A DEVICE FOR THE FORMATION OF A CORRECTIVE SIGNAL OF A TELEVISION SENSOR, containing serially connected paraphase force unit, a first switch and a weight summing unit, a synchronizer that, in order to improve speed and accuracy in the formation of a correction signal, consecutively connected units are put into a unit. the first output of the synchronizer, the memory block of the current values of the components of the correction signal, the second switch and the block, the digital-analogue converters, the output of which is connected to the input of a block of paraphase amplifiers, a block of memory of the average values of the components of the correction signal is input, the output of which is connected to the second input of the second switch and a block of level fixing is inserted, the signal input of which is connected to the bridge of the weight summing unit, the control input is connected from sec. B4 of the synchronizer and the control input of the second switch, and the output of the level fixing unit is connected to the control input of the television sensor, while the control input of the transducer Vågå commutative: vesovsro summing unit and torus are the phase control inputs and the control mode Lemma respectively. l ch1 co

Description

The invention relates to television and can be used as part of television, (TV) systems for correcting distortion of TV sensors on a real-time basis. A device for generating a corrective signal comprising a series-connected control unit, a first integrator, a first adder, a second integrator, a second adder, an adjustable amplifier and a modulator, a third integrator connected in series, a third adder, and a fourth integrator, whose output is connected to the second input of the second adder. The output of the first switch is connected to the control inputs of the first and second integrators and modulator. The output of the second key is connected to the control inputs of its third and fourth integrators. The inputs of the first and second keys are the inputs of the horizontal sync and vertical sync pulses, respectively. In addition, the second, third, fourth, and fifth outputs of the control unit are connected to the second input of the first adder, to the input of the third integrator, to the second input of the third adder, and to the control input of the adjustable amplifier accordingly. The modulator output is connected to the TB actuator M sensor. This device generates a correction signal to compensate for the unevenness of the TV signal in the form of a weighted sawtooth and parabolic components of the horizontal and frame frequency. The luminance, coordinate distortions and distortions of the spectrum of spatial frequencies of TV sensors are well approximated by full two-dimensional polynomials up to the fourth power. Therefore, the accuracy of the correction of the listed distortions by this device is low; in addition, the low response rate during the formation of the correction signal. This is due to the fact that the degrees of the polynomial, although they form a system of mutually independent components of two signals, are not orthogonal signals. In this connection, the formation of a correction signal by adjusting the voltage (by the control unit}, which controls the coefficients of the component signals, takes considerable time, since the formation process is associated with the repeated adjustment of the control voltages. The closest to the invention by technical essence a device for generating a correction signal TV sensor comprising a series-connected paraphase amplifier unit, a switch, a weight sum unit and a TV sensor, synchronize p, the first output of which is connected to the inputs of the sawtooth and parabolic horizontal frequency voltage generators, and the second output to the inputs of the sawtooth and parabolic horizontal frequency voltage generators. The outputs of the sawtooth and parabolic horizontal and vertical frequency generators are connected to the four inputs of the paraphase amplifier unit 2. A disadvantage of the known device is a low response rate when generating a correction signal for correcting distortions of the TV sensor. This is due to the fact that the correction signal is formed in the form of the sum of sawtooth and parabolic components of the horizontal and frame frequencies, which can be approximated by a two-dimensional polynomial as the sum of the simplest degrees that are not orthogonal to each other on the TV raster area. Therefore, when forming a correction signal, setting up a separate one of the four components of the correction signal will depend on the tuning flag of the other three components at a given time, which leads to repeated adjustment of the components of the correction signal using the successive approximation method to obtain the best possible correction for TV distortions. sensor. Another significant drawback of the known device is the low accuracy of the formation of the correction signal, due to the fact that the generated correction signal is described by a two-dimensional second-degree polynomial in which there are no mixed terms. Therefore, it cannot be used for the correction of non-affine distortions, for example, coordinate distortions such as trapezium, rhombus, pillow. In addition, the method of successive adjustments used in the formation of a correction signal always implies a residual tuning error. The purpose of the invention is to improve the accuracy and speed of the formation of the correction signal TV sensor. The goal is achieved in that the device for generating a correction signal TV sensor containing serially connected paraphase amplifiers, the first switch and the weight summing unit, a synchronizer, are sequentially connected to the addressing unit, whose input is connected to the first output of the synchronizer, current value memory the components of the correction signal, the second switch and the block of digital-to-analog converters, the output of which is connected to the input of the block of the paraphase amplifiers, are entered and the average values of the components of the correction signal, the output of which is connected to the second input of the second switch and a level lock unit is inserted, the signal input of which is connected to the output of the weight summing unit, the control input connected to the second output of the synchronizer and the control switch of the second switch and the code of the fixation block is connected to the control input of the TV sensor, while the control inputs of the first switch and the weight summing block are the inputs of the phase control and the module control according to governmental. The drawing shows a structure-wiring diagram of a device for generating a correction signal TV sensor. The device for shaping the correction signal of the TV sensor comprises the first switch 1, the weight summing unit 2, the synchronizer 3, the addressing unit 4, the current value component memory unit 5 of the correction signal, the second switch 6, the digital-to-analog converter unit 7 and the para-amplifiers unit 8 , block 9 of the memory of the average values of the components of the corrective scaling, block 10 level fixation and the TV sensor 11. Moreover, the first switch 1 and the block 2 weighing control have inputs of phase control and module control, respectively venno which are controllable inputs predpagaemogo device. The device works as follows. Clock pulses, synchronous with the scan TV sensor 11, are received from the first output of the synchronizer 3 to the input of the block 4 addressing. The addressing unit 4 generates a binary code address signal synchronously varying with the arrival of the clock pulses, which is fed to the input of the current value memory unit 5 by means of a correction signal to control the reading of information from its cells. In the cells of block 5, the current samples for each of the M components of the correction signal at the reference points evenly distributed over the area of the TV raster are recorded as a K-bit binary code. The number of control points, determined by the period of the clocking pulses, determines the accuracy of forming the components of the correction signal, and the number M of the components of the correction signal - / / the accuracy of forming the correction signal when correcting for the TV sensor distortions. In M of permanent memory devices of block 5, the values of samples M orthogonal relative to each other within the TV raster of component signals, for example, approximated by Legendre polynomials, are programmatically recorded. Chebyshev, etc., previously calculated by known formulas and shifted to the region of positive values. Sampling is performed in order to apply universal single-pole digital-to-analog converters in block 7 of digital-to-analogue converters. The sampling codes are sent via the MK-bit dn data bus to the first input of the second F4ator 6, to the second input of which the binary codes of the mean values of the displaced orthogonal components from the output of the block 9 arrive via the MK-bit data bus. the component of the non-zero order over the TV sweep period is zero, the average value of each offset orthogonal component over the TV sweep period is equal to its offset. On manager

the input of the second switch 6 is supplied with damping pulses from the second output of the synchronizer-3. At the same time, the output of the switch 6 receives the code of its average value for each component during the reverse sweep stroke, and the current value of the current . Codes from the code of the second switch 6 are received on the MK-discharge data line to the input of block 7 of digital-to-analog converters, which consists of M digital-to-analog converters. At the output of block 7 are formed in analog form in

the forward sweep time of the TV sweep M of the shifted orthogonal components of the correction signal synchronous with the TV sweep. During the reverse stroke of the TV sweep, the value of each component is equal to its average value during the working stroke of the sweep. The biased orthogonal components, formed in analog form, from the output of block 7 of digital-to-analog converters are fed via an MD data bus to the input, block 8 of paraphase amplifiers composed of M paraphase amplifiers, which each component forms two antiphase components. From the output of block 8, a 2M-bit data bus is fed by two phases of each component to the input of the first switch 1, which passes a phase necessary for forming a correction signal to its own component; This switch is made by applying a phase control to the input.

switch 1 via an M-bit data bus of an M-bit binary code from an external device representing, for example, a reprogrammable memory device. The change of this code is carried out only when forming (selecting the phases of the components) a correction signal manually or automatically cannot be non-synchronous with the TV scan. The switched phases are supplied by an M-bit data bus to the input of the weight summing unit 2. Yelok 2 determines the magnitude (weight) of each of the M components in the correction signal by supplying its control input from an external device via an MR1 data bus to the M signals

controlling the components of the module in the form of a P-bit double code each. The change of the codes of these control signals is also carried out only when a correction signal is formed (selecting the weight of the components) and may not be synchronous with the TV scan. At the output of block 2, a correction signal is generated in the form of a weighted sum of M offset orthogonal component signals. A correction signal generated by the weight summing unit 2, generated synchronously with the TV sweep, is fed to the signal input of the level fixing unit 10, to control which input the damping pulses are received. Block 10 fixes a zero potential in the correction signal during the quenching of 1 pulse, thereby prohibiting the correction during the reverse stroke of the TV sweep and eliminating the displacement of the orthogonal components during the direct stroke of the TV sweep, as during the damping pulses. of the shifted orthogonal components is equal to its offset. Thus, at the output of the level fixing unit 10, a correction signal is generated in the form of a weighted sum orthogonal to each other over the period of the forward stroke of the TV sweep component signals. The generated correction signal is applied to correct the distortion of the TV sensor 11 to its control input. The control input of the TV sensor is determined by the type of corrector distortion. Thus, to correct the coordinate distortions of the spectrum of spatial frequencies, it is necessary to send a correction signal to the focusing-deflection sensor system 11 of the sensor 11, and to correct the distortion, you can enter the correction signal in an additive and multiplicative way in the TV, using a controlled amplifier. Dp correction kaidogo iid distortion

The TV sensor needs to form its own correction signal. The process of forming a correction signal by the proposed device can be divided into two stages: the first - shaping (generating) the orthogonal components of the correction signal, the second - the formation of the correction signal itself by weighting these components in accordance with the control signals. from an external device. Since different correction signals are formed from the same components (since different types of distortions can be approximated by similar polynomials), the blocks: synchronizer 3, addressing unit 4, current value memory unit 5 are corrective signal, memory unit 9 These average values of the correction signal, the second commutator 6, the BLR 7 digital-to-analog converters and the block 8 paraphase amplifiers are COMMON-1F1 (they should not be duplicated) when generating these corrected PS signals.

The introduction and design of new units favorably distinguishes it from the known device for generating a correction signal TV sensor ;. The invention has a higher response rate, since the components of the HI formed by the corrective signal are orthogonal to each other in the TV raster area. Therefore, setting up the control signals from the entire device, which is independent. the weight and phase of the component in the correction signal is produced independently of each component, the formation of the correction signal ends in one tuning cycle. The proposed device forms the correction signal with a higher accuracy than the known one. This is due to the fact that the correction signal formed by it represents a complete two-dimensional polynomial (in which mixed members are also present) of an arbitrary degree (up to the fourth degree inclusive), therefore, it approximates well the distortion of the TV sensor. In addition, the elimination of the iterative tuning cycle also affects the accuracy of the formation of the correction signal.

The invention makes it possible to increase the response rate of the formation of a correction signal by a factor of 3–4 compared with the known one, both with manual and automatic KCKeoKeHtA TV sensors, and to increase accuracy by 2–2.5 times, ensuring more effective use over time. expensive TV systems and the high quality of information transmitted19 ".

Claims (1)

DEVICE FOR FORMING A CORRECTING SIGNAL OF A TELEVISION SENSOR, comprising a series-connected block of paraphase amplifiers, a first switch and a weight summing unit, a synchronizer characterized in that, in order to increase the speed and accuracy of generating a correction signal, a series-connected addressing block is connected, the input of which is connected to the first input synchronizer, a memory block of the current values of the components of the correction signal, the second switch and the block, digital-to-analog pre developers, the output of which is connected to the input of the block of phase amplifiers, a memory block of the average values of the components of the correction signal is inserted, the output of which is connected to the second input of the second switch, and a block of level fixation is introduced, the signal input of which is connected to the output of the weight summing block, the control input is connected to the second the output of the synchronizer and the control input of the second switch, and the output of the level fixing unit is connected to the control input of the television sensor, while the control inputs of the first the mutator and the weight summing unit are the Phase control and module control inputs, respectively. > 1 1125772 2