SU1149439A1 - Method and device for measuring amplitude-frequency characteristic and characteristic of relative phase progation time in television system - Google Patents

Abstract

1. A method for measuring the amplitude-frequency characteristic and characteristic of the relative phase propagation time in a television (TV) system, consisting in forming a test signal on the transmitting side, summing the test signal with the TV signal, then transmitting it through the measured TV system path B11 and selecting it on the receiving side test signal, measuring changes in the amplitude and form of its pulses, the magnitude of which is proportional to changes in the amplitude-frequency characteristic and character acteristic relative propagation time phase, featuring .i and in that, in order to increase the measurement accuracy, as a test signal on the transmitting side using a sequence of difference U sinuskvadratichnyh pulses of different duration. the amplitude of each of which is inversely proportional to the duration of the difference sinuskvadratichesky pulse, and at the receiving side, relative changes in the follow-up period of the track are measured by adjacent differential sinuskvadratichesky pulses of different duration, the value of which is proportional to the characteristic of the relative time of phase propagation, while parallel to the measurement of changes in the follow-up period adjacent differential sinuskvadraticheskim pulses of various duration transform difference sinuskadratichesky pulses in the sinuskadratichesky pulses, measured (L change their amplitude from the duration of the differential sinuskvadraticheskih pulses and summed with a signal proportional to the characteristic of the relative propagation time of the phase. 2.Part 4, different from: the side of the sequence from the AND difference sinuskvadratCHO pulses align the amplitudes of the difference sinuskvadraticheskih pulses of various durations, and on the receiving side before Eren relative changes in repetition period between adjacent difference sinuskvadratichnymi pulses of varying duration t proidvod inverse transform and amplitude difference sinuskvadratichnyh pulses. 3. Device for measuring the amplitude-frequency characteristic and xa

Description

The relative phase propagation time characteristics of the television system containing the mixer and the first synchronization driver, the first inputs of which are combined and the device input, the first and second inputs of which are connected to the second input of the mixer and the input of the driver of the test signals, the output of the mixer through the block of controlled functional elements are connected to the first inputs of the test signal selector and the second synchronization signal generator, the second input of which is connected with the first output of the test signal selector, the second output of which is connected to the first input of the measuring information control unit, the first of which is connected to the third input of the second synchronization signal generator, the second output is connected to the first input of the reference signal generator, the first and second outputs of which are connected to the second input of the unit , control of the measurement information and with the fourth input of the second generator of the synchronization signals, respectively, the outputs of the control signals of which are connected to The control signals of the test signal selector, the reference signal generator and the measuring information control unit, characterized in that, in order to increase the measurement accuracy of the amplitude-frequency characteristic and the characteristic phase propagation time, the successively connected differential pulse shaper and amplitude modulator, output are entered into it which is connected to the third input of the mixer, and the second input - to the third output of the first shaper of the synchronization signals, a quarter of you Which is connected to the control input of the differential pulse former, the input of which is connected to the output of the test signal generator, in addition, the first amplitude demodulator, the input of which is connected to the output of the test signal selector, demultiplexer, frequency selector, pulse repetition frequency converter and a time interval meter, three outputs of which are connected to the second input of the driver, which supports signals, to the third input of the contact block The measurement information rolls and the fifth input of the second shaper of the synchronization signals, respectively, also connected in series are the recovery signal test unit, the input of the reference signals of which is connected to the output of the shaper of the reference signals, and the second input is connected to the second output of the pulse repetition frequency converter, multiplexer and the second. amplitude demodulator, the output of which is connected to the fourth input of the measuring information control unit, and the second input to the fourth output from The time interval meter, the fifth input of the measuring information control unit is connected to the second multiplexer output, and the control signal outputs of the second synchronization signal generator are connected to the corresponding inputs of the first amplitude demodulator, pulse repetition frequency converter, time interval meter and multiplexer.

The invention relates to radio engineering and can be used in measurements of the amplitude-frequency characteristic (AFC) and the characteristics of the relative phase propagation time (RFM) in television (TV) and

other types of systems with transmission. electrical signals.

The known method of measuring the frequency response and the characteristics of the relative phase propagation time of the functional elements of the TV system path is based on the formation of a test sinusoidal signal of a sweeping frequency with a duration equal to the half-time of the generated signal by quenching line frequency pulses, adding the formed signal to the synchronizing line frequency pulses and on a periodic measurement of the magnitude of the relative changes in the amplitude and phase of the generated signals in a time equal to e test signal duration as a function of varying frequency L.  However, this method is characterized by the complexity of implementation and reduction of measurement accuracy with an increase in the rate of change of frequency with time.  Because of this, the duration of the test signal of the oscillating frequency is chosen relatively long, which seriously complicates the measurements in the course of operation, for example, a TV system. In addition, the measurement accuracy of the devices is also reduced due to the mutual influence of the distorted frequency response on the measurement results of the characteristics of the group propagation time and vice versa.  The magnitude of the mutual influence of the shape of the characteristics on the measurement results and, consequently, the magnitude of the measurement error increases with the complication of the shape of the measured characteristics.  The closest in technical essence to the present invention is a method for measuring the amplitude-frequency characteristics and characteristics of the relative phase propagation time in a television system, consisting in fsmming the test signal on the transmitting side, summing the test signal with the TV signal and transmitting it through the measured path of the TV system and on the receiving side of the test signal, measuring changes in the amplitude and shape of its pulses, the magnitude of which is proportional to Frequency response and characteristics OVFF tract system TV 2}.  The closest in technical essence to the present invention is an amplitude-frequency measurement device. characteristics and characteristics of the relative phase propagation time in a television system, containing in parallel 394 a mixer and. the first synchronization signal generator, the first inputs of which are connected and are the input of the device, the first and second inputs of which are connected to the second input of the mixer and the input of the test signal generator, the mixer output is connected to the first inputs of the test signal selector and the second synchronization signal generator through the block of monitored elements, the second input of which is connected to the first output of the test signal selector, the second output of which is connected to the first input of the control unit measure The first output is connected to the third input of the second formate & g of synchronization signals, the second output is connected to the first input of the reference signal generator, the first and second outputs of which are connected to the second input of the measuring information control unit and the fourth input of the second generator of synchronization signals The outputs of the control signals are connected to the control inputs of the test signal selector,.  driver of reference signals, measuring information control unit 2.  However, the known method and device.  The software does not provide the necessary accuracy of measurement due to difficulties in separating the distortions, which correspond to the effects of the phase-frequency and amplitude-frequency characteristics of the path, and the lack of noise immunity of the test pulses.  The purpose of the invention is to improve the measurement accuracy of the amplitude-frequency characteristic and characteristic with respect to the phase propagation time.  In order to achieve this goal, in the method of measuring the amplitude-frequency characteristic and characteristic of the phase propagation time in a television system consisting of a signal on the transmitting side of the test signal, summing the test signal with the TV signal and transmitting it through the measured path of the TV system and clicking on the receive signal test signal, measuring changes in the amplitude and shape of it, pulses, the magnitude of which is proportional to changes in the frequency response and Tickling of the RFMF, as a test signal on the transmitting side, use a sequence of n difference sinuskvadratic impulses (RSC) of various duration, the amplitude of which is inversely proportional to the duration of the CSC of the pulse, and at the receiving side measure the relative changes in the follow-up period between the adjacent CSC pulses of different the duration of which is proportional to the characteristic of the ORMF, while in parallel with the measurement of changes the period between adjacent impacted CSCs themselves of different durations convert CSC pulses into sinuskadratic pulses, erase the change of their succession from the duration of CSC pulses, and combine them with a signal proportional to the characteristic of the RFMF.  When pulses are formed on the transmitter side of ii CSC, the amplitudes of CSCs of pulses of different duration are aligned, and on the receiving side, before measuring relative changes in the follow-up period between adjacent CSC pulses of different duration, the amplitude of r PCC pulses is reversed.  ; For this purpose, in the device for measuring the amplitude-frequency characteristic and characteristics of the relative phase propagation time in the television system containing the mixer and the first synchronization signal generator, the first inputs of which are connected and are the input of the device, the first and second inputs of which are connected to the second input of the mixer and the input of the driver test signals, the output of the mixer through the block of controlled functional elements connected to the first inputs of the selector test signal and the second synchronization signal generator, the second input of which is connected to the first output of the test signal selector, the second output of which is connected to the first input of the measuring information control unit, the first output of which is connected to the third input of the second synchronization signal generator, the second output is connected to the first 1 39 the input of the driver of the reference signals, the first and the second, the outputs of which are connected to the second input of the control unit of the measuring information and the fourth input of the second driver of the signal synchronization respectively zshravleni signal outputs which are connected to the control inputs of the test signal selector.  the driver of the reference signals and the measuring information control unit, serially connected differential driver and amplitude modulator, the output of which is connected to the third INPUT of the mixer, and the second input with the third output of the first synchronization signal generator whose fourth output is connected to the control input of the differential pulse former, are inputted which is connected to the output of the test signal shaper, in addition, serially connected first amplitude signals are introduced a demodulator having an input connected to the output of the test signal selector, a demultiplexer, a frequency selector, the transmitter pulse repetition frequency.  and the time interval meter, three outputs of which are connected to the second input of the reference signal generator, with the third input of the measuring information control unit and the fifth input of the second synchronization signal generator, respectively, are also connected in series with the test recovery unit, the signals whose reference signals are connected with the output of the reference signal generator, and the second input is connected to the second output of the pulse repetition frequency converter, the multiplexer and the second am A loud demodulator, the output of which is connected to the fourth input of the measuring information control unit, and a second input to the fourth output of the time interval meter, the fifth input of the measuring information control unit is connected to the second multiplexer signal, and the outputs of the control signals of the second synchronization signal generator are connected with the corresponding inputs of the first amplitude demodulator, demultiplexer, pulse repetition frequency converter, time interval meter and multiplex exora  FIG.  Fig. 1 shows a structural electrical circuit of the device for measuring the amplitude-frequency characteristic and the characteristics of the relative phase propagation time in a television / television system; fig. Figures 2 and 3 show timing diagrams and dependencies illustrating the principles of measuring characteristics.  The proposed method is as follows.  Initially synphase and synchronous sequences of reference test pulses of sinuskadratic form are formed (Fig.  2ci).  At the same time, the duration of the reference test pulses of each subsequent sequence is changed, for example, shortened by a fixed interval with respect to the previous one.  The relative amplitude of the pulses of each sequence is set inversely proportional to the indicated changes in the duration of the reference test pulses (Fig.  2S, -2) and subtract the pulses of each previous one from each subsequent sequence.  From the results obtained by subtracting sequences of CSC pulses (Fig.  2, g) periodically form a common sequence of n different sinuskvadratic pulses of various durations, the amplitude of each of which is inversely proportional to the duration of the CSC pulse (Fig.  2a) In this case, the CSC pulses, corresponding to all the sequences of the sinusquadratic pulses obtained by subtracting, alternate in the general CSC pulse sequence with a fixed period (Fig.  2p.  The duration of the overall sequence is set to a multiple of the length of the TV signal line, and the period of formation of the overall sequence of CSC pulses is set to be a multiple of the frame duration (halfway) of the TV signal.  The total formed sequence of n CSC pulses is combined in time and in the amplitude range with a TV signal at the input of monitored elements of the TV system path.  and is distributed (FIG.  2i) in time at the output of the monitored elements of the TV system path into separate CSC yushulsy of various duration.  Then, the components of the spectrum of divided CSC pulses are filtered out, a cascade of which is repeated several times in time with a period, for example, equal to the period of their following within the total CSC pulse sequence at the input of the monitored elements of the TV system path.  The CSC sequence pulses obtained as a result of multiple repetitions limit the amplitude range and periodically form a series of auxiliary pulses, for example, of a rectangular shape, the follow-up phase of which is set in accordance with the phase of the CSC-limited pulses.  From the obtained sequences of rectangular igo-pulses, periodically form a common sequence of pulses of rectangular shape, in which with a period, a multiple of the pulse follow-up period within the overall sequence of CSC pulses, rectangular pulses from all the generated sequences of rectangular pulses are generated.  One of the formed sequences of rectangular pulses is converted into a sequence, the pulse period of which is set equal to the period of alternation of pulses in the general sequence of rectangular pulses, which are detected in phase or frequency.  In the case of phase detection, the signal after detection is differentiated and a signal is received that reflects the relative changes in the period to the melody by adjacent CSC pulses of various durations and is proportional to the relative-time characteristic of the phase propagation (ARF).  Some simplification in the measurement of ARFs is achieved due to the formation of a sequence of auxiliary pulses, the duration of which is changed in accordance with the relative changes in the interval between adjacent pulses in a common sequence of CSC pulses.  In this case, by detecting the pulse duration of the formed sequence of auxiliary pulses, a signal is obtained that reflects the relative changes in the period between adjacent RAC pulses of various duration.  In parallel with the measurement of the change in the follow-up period, the sinuskvadraticnaya form test pulses are restored from the rivers of the impulses of the sequences obtained as a result of multiple repetitions.  At the same time, the quality of recovery from the separated: filtered: bcc and multiple repetitive CSC pulses is automatically monitored.  the degree of suppression of negative emissions and the duration of the recovered pulse.  Of the restored. in this way, pulses periodically form a common sequence of test synus-quadratic pulses (FIG.  2k).  Detection in amplitude of the received sequence yields an envelope signal, section. This is a change in the average component of the sequence of recovered sinuswa pulses.  The envelope signal compensates for the component reflecting changes in the period of adjacent pulses of the overall sequence.  At the same time, the changes in the amplitude of the generated envelope signal are proportional to the changes in the frequency response of the monitored elements of the TV system.  The interference of test CSC pulses of relatively long duration increases due to the formation of a signal, the amplitude of which is proportional to the equivalent CSC duration of the pulses of the overall sequence.  Received signal. RAC amplitudes of the common sequence of such and-pulses at the input of the control elements of the TV system path amplify and equalize the amplitudes of the pulses at the output of the monitored elements. the total sequence of CSC pulses to the original relative values.  A device for measuring the frequency response and characteristics of ARMF (FIG.  1) contains mixer I, first shaper 2 synchronization signals, shaper 3 test signals, shaper 4 differential test impulses, amplitude modulator 5, block 6 controlled functional elements, second shaper 7 synchronization signals, selector 8 test signal, first amplitude demodulator 9, demultiploxor 10, frequency selector 11, transducer frequency converter 12, meter 13 time intervals, shaper 14 reference signals, unit 15 recovery test Yelnia signals, a multiplexer 16, a second amplitude demodulator 17, the control unit 18 of measurement information.  The device works as follows.  In the first driver 2, the synchronization signals are extracted from the original standard TV signal and converted into signals for control and synchronization of the transmitting part of the device.  In the driver of the 3 test signals and clock pulses, sequences of test sinuskvadraticheskogo forms of constant amplitude and fixed (shortest) duration are formed, which in the driver 4 are converted into in-phase and synchronous sequences of reference test pulses of sinuskvvraktratikichi forms of positive and negative polarity (fig.  2 a-2).  Moreover, in each subsequent sequence, the duration of the corresponding sinuskvadraticheskogo test pulse is changed by a fixed interval, for example, reduced.  The relative amplitude of the pulses in the transformed sequences is set inversely proportional to the change in the duration of the blue-square reference test pulses.  In the shaper 4, the reference pulses of each previous sequence are subtracted from each following one, the sequences of CSC pulses of different duration and amplitude Ui (t) -U2 (t) are obtained; U (t) -U5 (t); (FIG.  2e,) and by interleaving the RAC pulses with a given frequency in time, a common sequence of differential pulses is obtained (FIG.  2).  In the amplitude modulator 5, the amplitudes of the CSC pulses of the common sequence are changed according to the type of control signal from the first driver 2.  This increases the noise immunity of CSC pulses of longer duration and ultimately improves the accuracy of measurement of the frequency response and the characteristics of the ARF in the low frequency range.  In mixer 1, a total sequence of CSC pulses is inserted into the TV signal.  Distortion of the sequence of CSC pulses (FIG. 2i) are manifested in relative changes of amplitude and percod. following the RAC pulses of a common test sequence as compared with the original sequence (Fig.  2J).  In the second driver 7, the necessary synchronization and control signals are obtained.  In accordance with the control signal (SU) of the second form.  The driver 7 in the selector 8 performs the preliminary selection, processing, and transformation of the sequence of test pulses to the form required for the operation of subsequent blocks of the device.  In the first . the amplitude demodulator 9 realizes, with a reverse alignment in the transmitting part of the device, a change in the amplitudes of the CSC pulses of the common test sequence (FIG.  2 "), proportional to the SU from the second driver 7.  In the demultiplexer 10, in accordance with the control system, there is a general test sequence of division into separate (unchanged) RAC impises.  The frequency of the RAC pulses is usually equal to the frame rate of the TV signal.  . After temporal separation, these pulses arrive in frequency selector 11 to the corresponding frequency filter channels, the number of which is equal to the number of pulses separated by CSC.  The frequency response of the filtering channels of the frequency selector 11 are matched with the envelope of the spectrum of CSC pulses.  The view of the envelopes of the spectra of the sinuskadratic reference pulses and the CSC pulses is shown in FIG.  Zy & according to the functions of Son (f) and SOP (f).  It can be seen that when a measurement is passed, the duration of the CSC pulse is actual.  This method determines the working frequency range covered by the spectral components of a CSC pulse of a given duration.  Consequently, changes in the duration of the latter are accompanied by changes in the equivalent frequency range in which the measurements and characteristics are realized.  The significant localization of the spectrum, typical of differential sinusquadratic pulses, makes it possible to efficiently implement in the receiving part of devices frequency filtering of the spectral components of the separated test CSC pulses.  The form of the functional (f) determines the form of the frequency response in the individual filter channels of the frequency selector 11 (FIG.  3 &).  Due to repeated repetition of pulses separated in filtered CSCs, at the output of converter 12, auxiliary sequences (packs) of identical CSCs of pulses specified and fixed in 1 lines of auxiliary sequences (packs) of the following CSC pulses are formed in parallel.  This facilitates operation with low-frequency sequences of CSC pulses and provides ample opportunities for conversion, tuning, selection of the scale and type of signals, reflecting the measurement results at the output of the device.  The time interval meter can be implemented on the basis of phase frequency detection or pulse duration detection, generated sequences of auxiliary pulses.  During phase detection in the meter 13, the CSC pulse sequences are converted into the corresponding short square pulse sequences of the same tracking frequency.  Then, in the meter 13, by alternating in time rectangular pulses from each of the formed sequences, a common sequence of rectangular pulses is obtained, which is fed to one of the inputs of the phase detector.  In parallel, in the meter 13 a reference sequence of pulses is formed from the formed sequences of rectangular impulses, selected as the reference sequence, strobed at a frequency equal to the frequency of alternation of rectangular pulses in the common sequence, and is fed to the second input of the phase detector.  In the case of using a phase detector, it is necessary to enter a differentiation unit in the meter 13, which is connected to the output of the detector.  The amplitude of the signal at the output of de-.  The vector reflects changes in the relative delay of the CSC pulse duration and is proportional to the characteristic of the RFM.  The pulses of the meter 13 are fed to the driver 7, where they are used to form the corresponding control signals and the blue-square reference auxiliary pulses in the driver 14 (Fig. 2a, 8, b,).  However, the relative positions of the pulses of the indicated sequence are strictly consistent with the positions of the pulses, rectangular in shape from the meter 13 and, therefore, with the positions of the individual CSC pulses entering the input part of the device from the block 6.  In the shaper 14, signal sequences are also formed for self-control of the reception part of the device.  .  When summing up in block 15 test impulses of a sinuskadratic form with CSC pulses, the latter are converted into impulses of a sinuskadratic form of the corresponding (initial) duration.  By measuring at the output of block 15 the amplitude of negative outliers and the duration of the recovered sinuskvadratichnyh pulses, signals are generated by which the input amplitude, position and duration in time of the sinuskadraticnaya form, arriving at block 15 from formate equalizer 14.  In accordance with the SU coming from the second generator 7, the multiplexer-16 implements alternation with a predetermined period of time of single (or groups) test sinuskvadraticheskogo pulses from each of the recovered in block 15. sequences (FIG.  2k), corresponding to the general sequence of CSC pulses Ujp (t) (FIG.  2i).  In the second demodulator 17, the frequency response signal is extracted and the noise in the frequency response signal is compensated for due to phase distortions of the measuring sequence of CSC pulses of various durations.  From the signal obtained by measuring the envelope of the reconstructed sinuskvadratichesky pulses, the signal of the characteristic of the RFMF is subtracted.  In block 18, a comparative control of each of the specified characteristics is carried out, taking into account the specified tolerances for the corresponding distortions.  In shaper 7 and 14, using signals received from blocks 18, SUs and test signals of various purposes are formed.  The invention allows a significant increase in accuracy. measurement of AChC and characteristics of the OVFR of functional elements in the path of the TV system, provides full automation of measurements, reduces measurement time.  The invention allows, while retaining the merits inherent in measurements using test pulses, to strictly differentiate the distortion of test pulses associated with distortions of the path response elements from distortions associated with distortions of the phase-frequency characteristics of the elements of the path, and also makes it possible to strictly localize within the frequency range of each measurement site and change its position as the duration of the difference test pulse varies.  This is in ocHOBifOM and allows to ensure high accuracy of measurement of characteristics in the practical use of the proposed method and device for its implementation.

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Claims (1)

1. The method of measuring the amplitude-frequency characteristics and characteristics of the relative phase propagation time in a television (TV) system, which consists in generating a test signal on the transmitting side, summing the test signal with the TV signal, followed by transmission through the measured path of the TV system and isolating the test signal on the receiving side, measuring changes in the amplitude and shape of its pulses, the magnitude of which is proportional to changes in the amplitude-frequency characteristic and characteristics relative phase propagation time, which differs in that, in order to increase the measurement accuracy, a sequence of h difference sinusquadratic pulses of various durations, the amplitude of each of which is inversely proportional to the duration of the differential sinusquadratic pulse, is used as a test signal on the transmitting side. , and on the receiving side, the relative changes in the repetition period between adjacent difference sinusquare-square pulses of different durations are measured in time a value whose value is proportional to the characteristic of the relative propagation time of the phase, and in parallel with measuring the changes in the repetition period between adjacent difference sinusquadratic pulses of different durations, the difference ς is transformed. sine-squared pulses into sine-squared pulses, measure the change in their amplitude from the duration of the difference sine-squared pulses and summed with a signal proportional to the characteristic of the relative phase propagation time.