SU924917A1 - Device for measuring signal-to-fluctuation noise ratio - Google Patents

Description

(54) DEVICE FOR MEASURING THE RELATION OF A SIGNAL TO FLUCTULAR INTERFERENCE

The invention relates to television and can be used to measure the parameters of a complete television signal and a channel directly during transmission.

A device for measuring the ratio of signal to phpuctioisioi interference in television is known, which contains a sync separator, a series-connected weighing image, a reconditioning unit. the input of the weighing filter and the SI input of the spectrometer are the input of a full color image signal, and the output of the constant-restoration block is connected to the second input by utatora 13.

However, in the known device, it is necessary to use a rather complicated control circuit providing for the movement of gating pulses in

according to the laws of change in the frequency and phase of the subcarriers in a full color television signal, as well as the associated decrease in measurement accuracy.

The purpose of the invention is to show measurement accuracy.

Claims (1)

To achieve the specified circuit in the device for measuring the ratio of the signal to the fluctuation disturbance in television, it contains a sync selector, a weighted filter connected in series, a constant component recovery unit, a gating unit, a bandpass filter, an amplitude detector, a commutator, an analog-digital converter and a calculator, wherein the input of the weighing filter and the input of the sync selector are the input of the full color image signal, and the input of the DC-recovery unit; it is connected to the second input of the switch, a zone signal selector, a differencing unit and serially connected chrominance bandpass filter, a color lock signal selector and a comparator are entered, the sync output is connected to the second input of the comparator through a zone signal selector, to the second input of which the output of the color burst selector is connected, and the output of the band-pass chrominance filter is connected via a differentiation unit to the third input of the comparator, the output of which is connected to the second input of the gating unit, wherein the input of the bandpass chrominance filter is connected to the input of the syncrosector. FIG. 1 shows the structural electrical circuit of the proposed device; in fig. 2 - diagrams explaining his work. The device contains a weighing filter 1, a block 2 of restoring a constant component, a block 3 gating 1, a band pass filter (PF) 4, an amplitude detector 5, a switch 6, an analog-to-digital converter (ADC) 7, a cleaned 8 body, a synchro selector 9, a band-pass signal 10 color , a color synchronization signal selector 11, a zone signaling selector 12, a comparator 13 and a differentiating unit 14. The operation of the device is based on the example of gating a television (TV) signal by impulses following often the fields. Let the device receive the full color image of a dynamic image, the shape of which in two adjacent rows of adjacent fields is shown in FIG. 2a, a „. The impu ps B2 transmitted in the test lines carries information about the luminance signal sweep. The weighting filter 1 provides for the weighting of the fluctuation disturbance in order to account for its visual perception. When measuring the ratio of the signal to the unbalanced, fluctuating disturbance, the soiling filter 1 is turned off. Block 2 ensures the fixation of the level of the gus of pulses and, at the same time, the elimination of the effect of a change in the constant component of the TV signal on the measurement results. Next, the TV signal goes to the gating unit 3. In the case of the transfer of a black and white TV signal, the TV signal gating is carried out by pulses of short duration, which follow with frequency fields at any point of the active part of the selected line. Taking into account that the TV signal has a large coefficient of co-field by field, the spectrum of the converted signal is limited, the limiting frequency of the spectrum of the pre-converted signal F Q is less than the frequency, where T is the period of the following pulses. In this case, 2 Hz (ms). The conversion of the interference additively added to the TV signal leads to different ratios, taking into account that its samples taken at interval T are independent. Therefore, the spectrum of the converted interference is uniform in the frequency range from zero to F. At the same time, the statistical properties of the interference and, in particular, their effective voltages are equal. Parting of the spectrum of the converted interference is carried out with the help of the IF 4, the upper and lower limiting frequencies of which are associated with the frequencies FQ and Fpp by the relation PC-. . B - responsibly the lower and upper limiting frequencies of the PF 4). The effective interference voltage at the PF 4 output is proportional to the effective voltage of the TV signal interference. To obtain a constant voltage proportional to the effective voltage of the disturbance (or its square), an amplitude detector 5 is used. A quadratic detector can be used, the output of which is a voltage proportional to the square of the effective voltage, as well as a one-wavelength or two-wavelength linear detectors. In the case of a half pass of the IF 4 F Fg-F Fr-p, the distribution of the interference at its output becomes normal regardless of the distribution of the original interference. In this case, the voltage at the output of the linear detector is always proportional to the effective voltage of the disturbance. The TV signal from the output of block 2 and the constant voltage from the output of amplitude detector 5 are fed alternately through switch 6 to the input of ADC 7, which converts into digital codes of pulse width B2 (UN /) and voltage from the output of amplitude detector 5 proportional to the effective voltage of the fluctuation disturbance (Ug (k) These codes are successively fed to the calculator 8, which calculates the measured value directly in decibaps: H 202aj if its full color TV signal is supplied to the input of the meter Vapiy with frequency of fields in the same point of the active part of the selected line leads to the appearance of additional components of the converted signal due to the change of the color signal and phase switching of the subcarriers. Thus, in the SECAM system, two different color difference signals are transmitted on the subcarriers and the phases of the subcarriers commute by 180 degrees, two lines on the third and in each pope, while it is difficult to separate the spectrum of the converted noise from the spectrum of the converted signal. In order to ensure that the TF-4 is allocated to the part of the spectrum of the transformed interference, it is necessary to change the position of the gate pulse depending on the type of the transmitted chroma signal and the phase of the subcarriers. This is done as follows. The input TV signal is fed in parallel to the sync selector 9 and through the band-pass filter 10 of the chroma signal to the selector 11 of the color synchronization signal. The synchronizer 9 provides for the formation of pulses of two adjacent rows, in which the measurement of the level of fluctuation disturbances is made, and the selector 11 selects a bend of color synchronization signals corresponding to the transmission of the color difference signals Dp or Da (depending on which signal it is necessary to measure the fluctuation noise) . The signals from the synchrosector 9 and the selector 11 are fed to the selector 12 of the zone signal at the output of which pulses form in two adjacent fields (Fig. 26, b). The location of these pulses corresponds to the transmission of identical chrominance signals in a full color TV signal (for example, Df signals, as shown in Fig. 2a al), and their sections determine the active part of the selected lines, in which the level of fluctuation noise is measured. Pulses from the output of the selector 12 are fed from to the comparator 13, to the other input of which a chrominance signal is received from the band-pass filter 10 of the chrominance signal through the differentiation unit 14. At the output of it, the signals are separated in two adjacent lines (Fig. 2c., C), phase sinusoidal oscillations in which are shifted by 90 degrees relative to the phase of the color subcarriers in the full color TV signal. 76 When signals are supplied from the outputs of the selector 12 and the differentiating unit 14 of the comparator 13, pulses are generated (Fig. 2d, d), the cuts of which correspond to the positions of the pulses following the cuts (Fig. 2b / b, j) of the first zero crossings of sinusoidal oscillations (Fig. 2c, c). Consequently, the position of the pulse slices of Fig. 2d, g corresponds to the maxima of the color subcarriers in the full color TV signal (Fig. 2a, a). The oscillator located in the comparator 13 is started up in cut sections of figs 2g, d gating pulses, forming a signal of Fig. 2d, d, 2. which are used for gating the full color TV signal in the extremes of sinusoidal oscillations of the color subcarriers. Considering that the color difference signals transmitted in the SECAM system by the method of frequency modulation also have a large correlation coefficient over the fields and lines, transformed by the full color TV the signal has a spectrum limited by the frequency F JJ Therefore, the PF 4 provides for the selection of a part of the spectrum of the converted interference. Further signal processing is the same as described above. In the event that a TV signal without a color subcarrier arrives at the device input, this is detected by the absence of signals at the output of selector 11. At the same time, the strobe generator, which is located in the comparator 13, is started directly from the sync selector 9 through the zone signal selector 12. The proposed measure can also be used to determine the ratio of the signal to the fluctuation disturbance in the CT and NTSC signals. In this case, a color subcarrier flash is used as color timing signals. Tests of the proposed meter show that the measurement limit of the ratio of the signal to the fluctuation noise in the full color TV signal can be increased to 6O-7O dB with a measurement error of no more than 1 dB. Simplification of the circuit meter leads to a significant economic effect. Apparatus of the Invention A device for measuring the ratio of a signal to a fluctuating disturbance in temperament, containing a sync interceptor, connected to a weighted phyztr, a constant-condition repair unit, a gate sampler, a band-pass filter, an amplitude detector, a switch, an analog-to-digital converter, and a body figure, and a body figure, and a body figure, and a body part of it, and a body figure, and a body part of it, and a body part. filter and the input of the sync selector are the input of the full color image signal, and the output of the DC block of recovery is below (connected to the second at the input of the switch, characterized in that, in order to improve the measurement accuracy, a zone signal selector, a differentiating unit and serially connected bandpass filter, chromaticity, a color synchronization signal selector and a comparator are inserted in it, the output of the sync selector is connected to the second comparator input through the zone signal selector, to the second input of which the output of the color synchronization signal selector is connected, and the output of the band-pass filter of the power signal via the differentiation unit is connected to the third input of the comparator, the output of which is connected to the second input of the gating unit, while the input of the band-pass filter of the chromaticity signal is connected to the input of the sync selector. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 641674, cl. H 04N 7 / O2, 1976 (prototype). U