SU1273831A1 - Digital phasemeter - Google Patents

Abstract

The invention relates to the field of radio metering technology and can be used to construct digital phase meters with a wide dynamic and frequency range of the signals under study. The aim of the invention is to improve the speed and noise immunity of a digital phase meter. BTd ttai To achieve this goal, four pulse standardizers, a second reversible counter, two decoders and a trigger, as well as a pulse generator that is common to both channels, are added to each device in each channel. The drawing shows: identical channels 1 and 2, forming device 3, blocks 4 and 5, attachments to extreme values of the signal, consisting of elements 6, 7 and 8, 9 coincidence, stan-: dartizers 10, 11 and 12, 13, reversible counters 14 and 15, decoder 16 and 17, trigger 18, counting pulse generator 19, counting triggers (L ger 20, pulse sequence generator 21, pulse time conversion unit 22. Each standardizer includes D trigger 23 and element 24. 1 Cp f-crystals, 5 ill. ISD with 00 co

Description

The invention relates to a radio metering technique and can be used to build digital phase meters with a wide dynamic and frequency range of the studied signals.

Known digital phase meter with reference to the extreme values of the signal, containing in each channel [Interconnected Counter, memory register and code comparison unit, trigger and forming device, the output of which is connected to the counter input and the first trigger input connected by the second input of the code comparison unit, and output - with an input Record of a memory register, a counter pulse generator common to both channels and a time-pulse converter connected to it, including a time-divider connected in series, with associated with the inputs of the initial installation of the trigger and the memory register, an electronic key connected by inputs to the outputs of the code comparison unit and registering the counter.

The disadvantage of this phase meter is the limitation of the speed and accuracy of the measurement by reducing the number of phase intervals averaged over the measurement period.

A digital phase meter is also known, which contains pulse shapers in each channel at the moments of transitions of the studied voltages through zero values (hereinafter referred to as forming devices) and devices for isolating the moments of transitions of the studied voltages (signals) through maximum values that are associated with a common start circuit for both channels, a reference frequency generator and a time-pulse converter connected thereto, including a frequency multiplier connected to an electronic key connected to a recording device.

The disadvantage of such a phase meter is that in the absence of false zeros, reference pulses are generated through the signal period, which reduces the speed of the phase meter, as well as the fact that in the presence of false zero transitions, control triggers fail and the working and speed of the digital phase meter fail .

The purpose of the invention is improving speed and noise immunity.

This goal is achieved by the fact that four pulse standardizers are introduced in each channel into a digital phase meter containing a time-pulse converter with a counting pulse generator connected to it, · a counting trigger and two identical channels including a forming device, four coincidence elements and a reversible counter, a second reversible counter, two decoders and a trigger, as well as a pulse shaper common to both channels, which is connected by inputs to outputs of series-connected g a calculator pulse counter and a counting trigger, and the first output, with the inputs of the first and third coincidence elements connected, by the second inputs, respectively, to the direct and inverse outputs of the forming device, and the outputs, to the inputs of the corresponding pulse standardizers, which are connected by the second inputs to the second output of the pulse shaper sequences connected by the third output to the inputs of the second and fourth elements of matches associated with the second inputs respectively with the inverse and direct outputs of the forming device, and the outputs - with the inputs of the corresponding pulse standardizers, connected by the second inputs to the fourth output of the pulse shaper, and the outputs - with the second inputs of the first and second reversible counters, respectively, connected by the first inputs with the outputs of the first and third pulse standardizers, and the outputs with the inputs of decoders connected by the outputs to the third inputs of the second and fourth coincidence elements and the inputs of the trigger connected to the time-pulse output converter.

In this case, the pulse standardizer is made in the form of series-connected D-flip-flops and the And element, the output of which is the output of the pulse standardizer, and the second input connected to the C-input of the D-trigger is the second input of the pulse standardizer, the first input of which is the S-input D-flip-flop, whose D-input is connected to a logic zero level.

In FIG. 1 shows a block diagram 5 of a digital phase meter; in FIG. 2 block diagram of a pulse standardizer; in FIG. 3, 4 and 5 are timing diagrams of signals.

The phasometer contains two identical channels 1, 2, each of which includes a forming device 3 connected in series, the first and second blocks 4, 5 of binding to extreme values from the signal, consisting of 15 coincidence elements 6, 7 and 8, 9 , standardizers 10, 11 and -12, pulses, reversible counters and 15, and decoders 16 and 17 connected to trigger 18, common to both channels 20 and associated with them. with each other count pulse generator 19, a trigger counter 20, pulse generator 21 and a block 22 of sequences ²⁵ vremyaimpuls- transforma- tion. The pulse standardizer includes a series-connected D-trigger 23 and the element And 24.

The phasometer operates as follows 30 times.

The signals under investigation are fed to the forming devices 3 of the first and second channels 1, 2 of the phase meter, which convert them into a sequence of rectangular pulses, the edges of which correspond to signal transitions through the zero level. In FIG. Figure 3 shows the timing diagrams of signals for a case of sufficiently large 40 large signal-to-noise ratios, when there are no false zero-junctions due to broadband noise. In blocks 4, 5, bindings to the extreme values of the signal of both channels, pulses are generated (Figs. Sv, e), connected by negative fronts to the midpoints of the positive (in block 5) and negative (in block 4) half-waves of the signal, which corresponds to 50 times (without taking into account the delay in the forming devices) to the extreme values of the harmonic signal. The binding is carried out by digital integration of half-waves of the generated signal with a different time constant determined by the frequency of the counting pulses (Fig. 3 b,

e). In this case, during the action of the positive half-wave of the signal, the reverse counter 14 operates in the summing mode, and the reverse counter 15 operates in the subtraction mode, during the action of the negative half-wave of the signal, the operating modes of the reverse counters are reversed. In the summing mode, the inputs of the reversing counters 14, 15 through the elements 6, 8 matches and standardizers 10, 12 receive pulses from the shaper 21 pulse sequences with a repetition rate of / 2, in the mode of subtraction through the elements 7, 9 matches and standardizers 11, 13 pulses are received pulses of twice the repetition rate (Fig. 5). The moment of binding is recorded on the negative edge of the pulse at the output of the decoder (Fig. Sv, e), when the current code of the reverse counter (Fig. 3 b, e) in the subtraction mode takes a zero value, which is maintained until the end of the negative signal half-wave by locking the second and the fourth elements 7, 9 matches the output voltage of the corresponding decoder 16, 17.

The binding pulses are applied to the inputs of the trigger 18, which forms rectangular pulses (Fig. 3 g) with a duration equal to half the signal period and shifted relative to it by 90 in both channels (with strict symmetry of the output signals of the forming device 3, in the presence of asymmetry, the binding moment has a systematic offset compensated by two-half-time processing in the pulse-time conversion unit 22. Signals from the outputs of the triggers of both channels, as well as a sequence of counting pulses from the output of the generator 19 post falls on the inputs of the block 23 time-pulse conversion, where the formation of time intervals proportional to the measured phase difference of the signals, their encoding and registration.

The use of information on both extreme values of the signal in each period increases the speed and accuracy of the measurement by increasing by 4 times the number of averaged intervals for the same measurement time (in phase meters with averaging <).

In FIG. Figure 4 shows the timing diagrams of the operation of the phase meter, taking into account broadband noise, leading to multiple zero-level intersections (Fig. 4 a, d). Blocks binding to the extreme values of the signal in this case integrate over the duration of the emissions and pauses of the generated mixture of signal and noise (Fig. 4 bd). Moreover, in the region of zero transitions of a pure signal, where the outliers and pauses are commensurate in duration, during pauses, it is also possible to read the codes of the reverse counters 14, 15 to zero (in the region of positive zero transitions for the reverse counter 14 and in the region of negative zero transitions for the reversible counter 15), which corresponds to the formation of false binding pulses at the outputs of the decoders 16, 17 (Fig. 4 c, f).

• However, in the future, as the duration of the emissions is integrated, the current code of the reverse counters (Fig. 4 bd) increases, reaching a certain maximum value in the region of negative zero transitions (for reverse counter 14) and positive zero transitions (for reverse counter 15) . Further, pause durations become predominant, causing a decrease in the code of the reverse counters at a speed approximately 2 times greater than during its increase (during the action of the positive half-wave of the signal at the corresponding output of the forming device). When the code reaches a zero value, an anchor pulse is generated at the decoder output, which coincides on the negative edge with the accuracy determined by the noise and the corresponding extreme signal value. Thus formed anchor pulses (4, e) determine the state of the flip-flop 18, while false binding pulses lagging relative to their time, only ⁵⁰ confirmed give these conditions, not affecting the operation of the device. As a result, at the output of flip-flop 18, and each channel as well as in case of the clean signal, ⁵⁵ are formed of rectangular pulses of duration equal to half the signal period no false zeros (FIG, 4 g).

Thus, in the proposed device, an integral assessment of the temporary position of the signal extrema is carried out by analyzing the ratio of the average values of the residence time of the signal mixture and the noise above and below zero, the level in each signal period, which is predetermined. It has increased noise immunity. It is determined by such signal-to-noise ratios, in which false alarms and signal missing are possible.

When quantizing signal half-waves at the outputs of coincidence elements 6–9, counting pulses that are not standard in duration may appear. (when coinciding with the fronts of the quantized signal half-waves) and acting without any pause on the inputs of summing and subtracting the reverse counters. In addition, in the presence of noise, it is possible to split the counting pulses, · All this leads to failures of the reversible counters and a decrease in the accuracy and noise immunity of the phase meter. To eliminate this phenomenon, pulse trainer 21 and pulse standardizers 1013 are used, implemented, for example, in accordance with the block diagram of FIG. 2.

Shaper 21 pulse sequences generates two pairs of delayed relative to each other pulse sequences with a frequency of 1 _sf and £ _sch / 2 quantizing and synchronizing. The pulses of the quantizing sequence go to the inputs of the elements of 6-9 matches, connected by the outputs to the S-inputs of the D-flip-flops 23, and the pulses of the synchronizing sequence - to the C-inputs of the D-flip-flops 23 and the second inputs of the I-24 elements, connected by the first inputs to the outputs of the D-flip-flops. As a result, the outputs of the elements And 24 contain standard duration counting pulses corresponding to each operation of the D-flip-flops 23, and the pulses at the inputs of summing and subtracting the reversible counters are always separated in time, which eliminates the loss of information and the possibility of failure of the reversible counters, including due to the fragmentation of pulses during quantization.

Thus, the introduction of these elements and relationships allows to increase the speed and noise immunity of digital phase meters to internal and external broadband noise and, therefore, to expand the dynamic and frequency range of the studied signal-j traps.

Claims (2)

The invention relates to a radio measuring technique and can be used to construct digital phase meters with a wide dynamic and frequency range of the signals under study. A known digital phase meter with reference to extreme signal values, containing in each channel an interconnected counter, a memory register and a code comparison unit, a trigger and a shaping device, the output of which is connected to the counter input and the first trigger input connected by the second comparison unit input codes, and the output is with the input Record of the memory register, the generator of counting pulses common to both channels and the time-pulse converter connected to it, which includes series-connected time master divider associated with the inputs of the initial installation of the trigger and the memory register, an electronic key connected by inputs to the outputs by a code comparison unit and a registering counter. The disadvantage of this phase meter is the limitation of speed and accuracy of measurement by reducing the number of phase intervals averaged over the measurement time. Also known is a digital phase meter containing in each channel pulse formers at times of transition of the investigated voltages through zero values (hereinafter - forming devices) and devices for extracting the transition moments of the voltages under study through the maximum values that are associated with both channels a start-up circuit, a reference frequency generator and a time connected to it a pulse converter, including a frequency multiplier, connected to an electronic key connected to a transmitting device by trio. The disadvantage of such a phase meter is that, in the absence of false zeros, pulses to the maximum signal values are formed through the signal period, which reduces the speed of the phase meter, and that in the presence of false zero transitions, control triggers and losses are observed The 312 type and speed of the digital phase meter work well. The purpose of the invention is to improve the speed and noise immunity. This goal is achieved by the fact that in a digital phase meter containing a time pulse converter with a counting mp3 generator connected to it, a counting trigger and two identical channels, including an airing device, four coincidence elements and a reversing meter, four pulse standardizers are inserted in each channel , the second Eversive counter, two decoders and a trigger, as well as a pulse generator generator common to both channels, which is connected by inputs to the outputs of a series-connected generator and the counting pulses and the counting trigger, and the first output - with the inputs of the first and third coincidence elements connected, with the second inputs respectively to the forward and inverse outputs of the shaping device, and the outputs - to the inputs of the corresponding pulse estimator standards, which are connected by the second inputs to the second output a pulse sequence generator connected by the third output to the inputs of the second and fourth elements of coincidence connected by the second inputs to the inverse and direct outputs respectively and outputs - with the inputs of the corresponding pulse standardizers connected by the second inputs to the fourth output of the pulse pattern generator, and outputs to the second inputs of the first and second reversible counters connected by the first inputs to the outputs of the first and third pulse standardizers, and outputs to the inputs of the decoders connected by the outputs to the third inputs of the second and fourth elements of the match and the inputs of the trigger connected by the output to the time pulse th transmitter. In this case, the pulse standardizer is implemented as a series-connected D-flip-flop and an element, whose output is the output of the pulse standardizer, and the second input connected to the C-input of the D-flip-flop is the second input of the pulse standardizer, the first input of which is S- input of the D-flip-flop, the D-of which is connected to the logical zero level. FIG. 1 shows a block diagram of a digital phase meter; in fig. 2 is a block diagram of the pulse standardizer in FIG. 3, 4 and 5 are time diagrams of signals. The phase meter contains two identical channels 1, 2, each of which includes a series-connected forming device 3, the first and the second blocks 4, 5, which bind to the extrinsic values of the signal, consisting of elements 6, 7 and 8, 9 matches, standardizers of 10, 11 and -12 13 pulses, reversible counters 14 and 15 and decoders 16 and 17, connected to trigger 18, common to both channels and associated with them and with each other generator 19 counting pulses, counting trigger 20 , shaper 21 pulse sequences and block 22 pulse time edu. The pulse standardizer includes a D-flip-flop 23 and an AND 24 element connected in series. The phase meter operates as follows. The signals under study are fed to the forming devices 3 of the first and second channels 1, 2 of the phase meter, which convert them into a sequence of square pulses, the fronts of which correspond to signal transitions through the zero level. FIG. Figure 3 shows signal timing diagrams for the case of sufficiently large signal-to-noise ratios, when false zero transitions due to broadband noise are absent. In blocks 4, 5 of the signal to extreme values of the signal of both channels, pulses are formed (Fig. 3c, e), associated with negative fronts to the midpoints of the positive (in block 5) and negative (in block 4) half-waves of the signal, which corresponds in time (without taking into account the delay in the shaping devices) to the extreme values of the harmonic signal. Binding is carried out by digital integration of a half-wave-shaped signal with a different time constant, determined by the frequency of the counting pulses (Fig. 36, 8314 d). In this case, during the positive half-wave of the signal, the reversible counter 14 operates in the summation mode, and the reversible counter 15 - in the subtraction mode, while the negative half-wave signal acts, the operating modes of the reversible counters are reversed. In the summation mode, the inputs of the reversible counters 14, 15 through the elements 6, 8 coincidence and standardizers 10, 12 receive pulses from the generator of 21 pulse sequences with the following frequency / 2, in the subtraction mode through the elements 7, 9 coincidences and standardizers 11, 13 pulses arrive and two times the following frequency (Fig. 5). The anchor point is recorded by the negative pulse front at the output of the decoder (Fig. 3c, e) when the current code of the reversible counter (Fig. 3b, e) in the subtraction mode takes a zero value, which is maintained until the negative half-wave signal is terminated by locking the second and fourth elements 7, 9 coincides with the output voltage of the corresponding decoder 16, 17. The coupling pulses arrive at the inputs of the trigger 18, which forms rectangular pulses (Fig. 3 g) with a duration equal to half the signal period, and shifted relative to it by 90 in both channels (with strict symmetry of the output signals of the shaping device 3, when asymmetry is present, the anchor point has a systematic offset compensated by full-wave processing in the block 22 of the pulse conversion time. The signals from the outputs of the trigger of both channels, as well as the sequence counting pulses from the output of the generator 19 is fed to the inputs of block 23, the time of pulse conversion, where the formation of time intervals proportional to my phase difference signals, their coding and registration. The use of information on both extreme values of the signal in each period increases the speed and measurement accuracy by increasing by 4 times the number of averaged intervals during the same measurement time (in phase meters with averaging). FIG. Figure 4 shows the time diagrams of the phase meter operation, taking into account the broadband noise resulting in multiple zero-level crossings (Fig. 4a, d). In this case, the blocks of attachment to extreme values of the signal are carried out by integrating over the duration of the emissions and pauses of the formed mixture of signal and noise (Fig. 4 b). At the same time, in the zero-transition region of the pure signal, where the outliers and pauses are comparable in duration, during the pause action, it is also possible to read the return estimator codes 14, 15 to zero value (in the positive zero-first entry region for the reverse counter 14 and in the area of negative zero transitions for the reversible counter 15), which corresponds to the formation of spurious lock pulses at the outputs of the decoders 16, 17 (Fig. 4c, e). However, later on, as the duration of the emissions is integrated, the current code of the reversible counters (Fig. 4 b) e increases, reaching some maximum value in the area of negative zero transitions (for reversible counter 14) and positive zero transitions (for reversible counter 15). Further, the pauses become predominant, causing the code of the reverse counters to decrease with a speed about 2 times greater than when it rises (during a positive half-wave signal at the corresponding output of the shaping device). At the moment when the zero value reaches the output of the decoder, an anchoring impulse is generated, which coincides on the negative front with an accuracy determined by noise with the corresponding extreme value of the signal. The binding pulses generated in this way (4, e) determine the state of trigger 18, while false anchor pulses lagging behind them in time only confirm these conditions without affecting the operation of the device. As a result, at the output of the flip-flop 18 and the rear channel, as well as in the case of a clean signal, right angle pulses of a duration equal to half the signal period without false zeros are formed (FIG. 4). Thus, in the proposed device, an integral estimate of the temporal position of the signal extremums is carried out by analyzing the ratio of the average values of the signal mixture residence time and noise above and below the zero level in each signal period, which is predetermined, and its increased immunity. It is determined by such signal-to-noise ratios, at which false positives and signal skips are possible. When quantizing the half-wave at the outputs of the coincidence elements 6–9, the occurrence of non-standard counting pulses is possible (if the fronts of the quantized half-wave signal coincide) and affecting the inputs of summation and subtraction of reversible counters without any pause. In addition, in the presence of noise, the fragmentation of counting pulses is possible. All this leads to the failure of reversible counters and a decrease in the accuracy and noise tolerance of the phase meter. In order to eliminate this phenomenon, the pulse shaper 21 and pulse standardizers 1013 are implemented, for example, implemented in accordance with the flowchart of FIG. 2. Shaper 21 pulse sequences form two pairs of delayed relative to each other pulse sequences with frequency tg and / 2 quantizing and synchronizing. The pulses of the quantizing sequence are fed to the inputs of elements 6–9 coincidences connected by the outputs to the S-inputs of D-flip-flops 23, and the pulses of the synchronization sequence to the C-inputs of D-triggers 23 and the second inputs of elements And 24 connected by the first inputs to the outputs of D-flip-flops. As a result, the outputs of the And 24 elements contain standard counting pulses corresponding to each D-flip-flop 23, and the pulses at the inputs of the summation and subtraction of the reversible counters are always spaced in time, which eliminates information loss and the possibility of reversible counters, g th number and by splitting pulses when quantizing. Thus, the introduction of these elements and connections allows one to increase the speed and noise immunity of digital phase meters to internal and external broadband noise and, moreover, to expand the dynamic and frequency range of the signals under study. Claims 1. A digital phase meter comprising a pulse converter with a counting pulse generator, a counting trigger and two identical channels, including a shaping device, a matching four element and a reversible counter, characterized in that, in order to improve speed and noise immunity , a pulse mash standard, a second reversible counter, two decoders and a trigger, as well as a pulse generator sequencer common to both channels, are entered into it in each channel; Information that is connected by inputs to the outputs of a series-connected counting pulse generator and a counting trigger, and the first output to the inputs of the first and third match elements connected by the second inputs to the direct and inverse outputs of the forming unit, respectively, and the outputs to the inputs of the corresponding standardizers of pulses which are connected by the second inputs 8318 dami with the second output of the pulse shaper sequence generator connected by the third output to the inputs of the second and fourth elements drops connected by the second inputs to the inverse and direct outputs of the forming unit, respectively, and the outputs to the inputs of the corresponding pulse standardizers connected by the second inputs to the fourth output of the pulse sequence generator, and the outputs to the second inputs of the first and second reversible counters connected by the first inputs with the outputs of the first and third pulse standardizers, and the outputs with the inputs of the decoders connected to the outputs with the third inputs of the second and fourth th items coincidence and trigger inputs connected to the output of the time pulse transmitter, 2. Phase meter according to claim 1, distinguishing between u and the fact that the pulse standardizer is executed as a series-connected D-flip-flop and an And element, with the S-input of the D-flip-flop and the second input connected to each other element And are respectively the first and second inputs of the pulse standardizer, the output of which is the output of the element And, the D input of the D-flip-flop is connected to the logic zero level. 6 in .t r-t g g e t t Jl. / ./ cfyue.3 I I and I I I I I FIG. cpue.5