SU746317A2 - Analyzer for distributing time interval probability between adjacent overshootings of random processes - Google Patents

Description

7 rs: A "S Siinfr li- - --v --Vi - -.: -: --- -.-- - f ----- - - -; —fine selection of device ranges from coarser to more accurate for obtaining the maximum likelihood of a histogram at the highest resolution, and this is due to the time spent on the analysis of the studied processes. The aim of the invention is to improve the accuracy and reduce the analysis time. . To this end, the analyzer of probability distributions of time intervals between adjacent emissions of random processes, additionally introduced two keys, a converter, analog code, a buffer register, a comparison unit, a counter, a control unit, and a statistical accuracy parameter setting unit, with the output the control unit is connected to the first inputs of the first and second key and to the input of the statistical parameter setting unit, the output of which is connected to the first input of the sravpeyush block, the second input of which is connected to the output b The first register, the first input of which is connected to the output of the second key, the second input is connected to the input frequency divider, the first input of the time-amplitude converter and connected to the output of the counter, the input of which is connected to the output of the Neni block, the output time-amplitude converter is connected to the second input of the buffer register and to the input of the analog-code converter, the output of which is connected to the second input of the second key and the output of the frequency divider, the output of the first key is connected to the input of the time field detection unit voltage vybrosav block diagram of the analyzer shown pas drawing. The analyzer contains the first switch 1, the block 2 for determining the temporary position of the surge, a precision line 3. for deersi, vra amplitude converter 4, multichannel amplitude analyzer 5, synchronizing microwave generator b, frequency divider 7, high-pass filter 8, frequency control unit 9, recirculation generator 10, 4 ltr 11 SCR, control unit 12, unit 13 CPA, second key 14, buffer register 15, CH1K 16 count, block 17 for specifying a parametrist of precision accuracy, converting analogue code 18, block 19 for generating time reference shifts. 7; ,: 4 - The analyzer works as follows. ... Investigated The random process through the first key is fed to the input of block 2, where the extreme outliers (maxima and minima) of the random process are separated from the studied implementation and the output pulses are generated standard in duration and amplitude, the temporal position of which corresponds to the set threshold level of the block discriminator input 2, Thus, at the beginning of block 2, a sequence of time intervals is formed, from which the races of the extreme extremes of the process under study are determined. To perform a continuous analysis cycle of a series of consecutive measuring intervals (time delay of a sequence of generated interval pulses using a precision delay line for the time required for the end of each measurement cycle. The beginning of the measurement interval of the measured intervals) is performed when applied to a precision {the delay and the amplitude transducer time are 4 sequences of interval pulses, c4) arranged in block 2. Precision delay line output signal and, delayed by the time Cg, 5 necessary for the end of the previous measurement cycle ty.j (ni), starts the recirculation of the generator 10 .. As a result, in phase with the output signal, the start of the precision delay line in the recirculation generator 10 is generated a series of pulses, which is a reference, and its beginning coincides with the interval pulse of the process under investigation, delayed by M on Bram. , , To stabilize the measuring series and to exclude the effect of the accumulation of fluctuations in the recirculation generator, a forced synchronization of its period is used. In the phase of the synchronizing reference microwave generator 6 in the Frequency Division mode. As a result, the timing of the recirculation of the wheel generator is synchronized according to the phase of the signal of the synchronization reference microwave generator 6. In this case, the stability of the period of the measuring series is completely determined by the initial stability of the synchronizing reference microwave generator 6. The measuring series of pulses of the recirculation generator 10 is fed to the input the divider 7 frequency measuring series, where the formation of a sequence of reference intervals t by recalculating the measuring series. In phase with output pulses of block 2, in parallel with the incoming signal to the output discrete delay line 3, the time-amplitude converter 4 is started and the interval measurement process starts () the next pulse of the sequence of divider reference intervals corresponding to the end of the measurement is fed to the second input time-amplitude converter 4 and turns it off, thus ending the process of measuring the interval AtnaM) of the output time-amplitude converter 4 signal, the amplitude of which is proportional to at measurement intervals Atj ,. (p), is fed to the input of a multichannel amplitude analyzer 15, in which each value of amplitude corresponds to its discrete channel of the storage device. The output signal of the multichannel analyzer is fed to the first input of the pulsed recirculation generator 10, where it blocks (oscillation failure) the measuring pulse train. The number of impulses of the sequence-35, Q reference intervals, stacked in the measured interval from the output of the divider 7 and the delay interval are recorded in parallel at each measurement peak. rHCTorpaMivia, recorded in the memory of the multichannel analyzer 5, is an exhaustive characteristic that allows one to obtain the necessary statistical estimates. The lack of a priori information about the processes under study when removing the hetograms causes the prototype to need to switch the range of the measuring series 7 frequency divider in the prototype and change the resolution of the time-amplitude converter in order to record the histograms with the highest possible accuracy of measurement (the greatest electrical resolution), which leads to a decrease in accuracy and speed, In the proposed device, the selection of the measuring range of the divider 7 is often s and synchronously with 1Shm dia-, pazona time of the amplitude of the transducer 4 is performed automatically as adaptation functionality structure analyzer during accumulation of statistical data as follows. The analyzer adaptation cycle begins when a fast component process appears in the implementation of the process under study. At the same time, the analyzer is produced from the conditions of the required statistical accuracy (which is specified through the block 12 of the control block 17 as the number of permissible outputs of the time codes of the buffer register 15 for the analysis range fixed in the block 13 comparing the time scale. On the command of the control block 12 the keys 11 and 14 are opened at the control inputs, after which the implementation under study is fed to the input block 2 and then the code combination obtained from the output of the converter in the measurement process The code 18 and at the same time the output series of the Frequency Divider are registered by the buffer recorder 15, after which the key 14 is closed again. The code message K sent to the buffer register is a measure, which is then compared to the reference form B received from the statistical parameter generation block 17 In the case when the dimension of the code premise K j is placed in the dimension of the reference brightness B J, the measurement result is recorded in the memory of the multichannel analyzer 5 and a new analysis cycle begins. When the fluctuation estimate is outside the range of comparison, (code send K 2,) of the process under study, a pulse appears at the output of the block. 13 (Mj, which is fixed (summed) by the counter 16, after which the buffer The register 15 and the following code combination from the output of the converter analog-code 18 are fixed by the buffer register 15 as a new measure for comparison and then the analysis cycles are repeated until a given statistical accuracy is reached. - When exceeding a given number of outputs (21 and n), the range (cycle P ) counter 16 (determined by fluctuations of the measured process) reorganizes the dimension of the analyzer's time scale, i.e. when counter 16 overflows, the analyzer q5a adapts and switches to the next (coarser range) frequency divider of the measuring series and synchronous converter 4. On This range of frequency divider and time-amplitude converter is again successively carried out a series of measuring cycles in the comparison unit, and then the range of block 7 is switched again (if the input process fluctuates strongly uroit). This adaptation process is repeated sequentially. Thus, the adaptive cycle for obtaining a distribution density gist of duration between adjacent outliers of random processes is as follows. From the a priori information about the process under study X (t), control block 12 through block 17 sets the number of outputs for the analyzer interpolation, which is equivalent to specifying the level of the pedestal (width of this distribution) of the recorded distributions. In the initial state, the range of analysis is established with a small: maximum resolution (minimum assumed -fluctuash). The maximum number of emissions from a random process is determined by the limit values of the memory of the multichannel analyzer 5. If the fluctuations of the process being studied are small, i.e. the number of specified out-of-range outputs does not exceed, then the histogram collection process is stopped when a given number of accumulations is reached in one of the channels. If fluk; Since the number of processes is significant, then the number of headings in this range exceeds the conditions of statistical accuracy, and after this, the next subrange range is automatically set from the larger pedestal width of the distribution. When satisfying a given statistical accuracy over this range, the set is terminated similarly in the || Failure to perform the adaptation, i.e. go to the next wider (coarse) range and so consistently to the last range. If, however, the conditions of the required statistical accuracy are not fulfilled even at the last season, then the production. It means that the analysis of the return of the analyzer to the initial state of the analyzer (maximum resolution) is carried out, new conditions of statistical accuracy are introduced, or the fact that the fluctuations of the process under investigation are beyond the maximum capabilities of the analyzer and cannot be measured by it with the specified statistical accuracy is indicated. In the automatic transition from range to range to meet the statistical accuracy requirement, the multichannel analyzer 5 records a consistent series of histograms with maximum resolution. From the point of view, the analyzer registers the limiting potential: the fluctuation range (while maintaining the electrical resolution) within the permissible number of analyzer channels, and any wide fluctuation range with deterioration of the electrical resolution, provided that the fluctuations exceed the range of the analyzer channel number, i.e. in the latter case, in order to preserve the entire pedestal of distribution, it is necessary to increase the quantization step, which is equivalent to the degradation of the electrical resolution. In the process of adaptation, the transition from sub-band to sub-band in the multichannel analyzer 5 is performed. Rapia of previous accumulations (histograms), as not meeting the specified conditions. Thus, the adaptive cycle and density of the distribution of duration between the emissions of random processes occurs automatically without participation of the operator until the conditions of the required statistical accuracy are satisfied at the maximum possible electrical resolution for this case. The possible measurement range of the adaptive analyzer ranges from 0.5 µs to several seconds with an electrical resolution of 1.10. The use of new elements — bu ({a registrar, a controlled circuit comparing 1 ”I, an analog-code converter, a detector, a comparison circuit, a programmer to the sensor of statistical accuracy) provides the following advantages over the prototype: 5) excludes a large number of measurements from the operator computed, but requires the presence of an operator in a long-term measurement process.

Claims (1)

Claim Probability Distribution Analyzer. According to author's certificate No. 515998, time intervals between outliers of random processes, which means that in order to increase the accuracy and reduce the analysis time, two keys are added to the analyzer, an analog-to-code converter, 15 buffer register, and a comparison unit , a counter, a control unit and a unit for setting the statistical accuracy parameter, while the output of the control unit is connected to the first inputs of the first and second of which is connected to the first input of the comparison unit, the second input of which is connected to the output of the buffer register, the first input of which is connected to the output of the second key, the second input is combined with the input of the frequency divider, with the first input of the time-amplitude converter and connected to the output of the counter, the input of which is connected to the output of the comparison unit, the output of the time-amplitude converter is connected to the second input buffer register and to the input of the converter is an analog-code, the output of which is connected to the second input of the second key and to the output of the frequency divider, the output of the first key is connected to the input of the temporary position determination unit a.