SU976494A1 - Method of forming orthogonal square-wave signals - Google Patents

Description

The invention relates to a pulse technique, in particular for obtaining an orthogonal rectangular signal system from an original periodic signal. The known method of obtaining orthogonal signals from the original oscillation involves the use of two active quadrupoles with interconnected inputs, in which the transmission coefficient of each is determined by the complex values of frequency II. However, this method has insufficient formation accuracy. The closest technical solution to this invention is the method, which consists in multiplying the original sinusoidal signal in frequency. four times, transforming one temporarily it into a sequence of rectangular pulses which are then divided by the frequency of the original two times, and then the received signal and the inverse one are again divided into two, for example, using a trigger c-signal, while receiving orthogonal rectangular impulses. The same frequency signal is multiplied by two (and then more than once by two 5 is carried out by converting the original inverted rectangular pulses into linearly increasing pulses with a short-term decrease, their summation and subsequent comparison with the reference constant voltage of 0.5 from Shituds of the increasing pulse pulses {2 j. However, the known method in a wide frequency range does not fundamentally allow the signals to be shifted relative to each other by TC / 2 more precisely than 1-2 °, especially during infrasonic oscillations due to About the fact that they are based on the use of frequency-dependent circuits of analogue technology, in particular for int, engraving, filtering and other processes. The purpose of the invention is to expand the frequency range and increase the accuracy of the shift between square signals. a method of forming orthogonal rectangular signals, in which rectangular pulses are formed separately for the direct and inverse values of the input periodic oscillation and the resulting time intervals are filled In the high frequency pulse, for a time interval of four periods, four low-frequency pulses of the same duration are formed, in which the leading edge of each subsequent coincides with the trailing edge of the previous one and in the sum equal to two periods of the initial oscillation, then for one channel the first low-frequency pulse is converted into a packet, the second and third are converted into analogous packs consisting of i of high-frequency pulses each, while Equalizing the second burst and the result obtained is summed with the number N corresponding to the third burst, after which at the trailing edge of the fourth low-frequency pulse the result is obtained, after which it is erased, as in the second channel, the described actions are carried out with a shift in time equal to two periods of the input, the oscillations, further fixing the signals corresponding to the zero results of the subtraction; .- and summing over both channels and summing them with the signals corresponding to the beginnings of each even period and repeating the indicated operations Preparation E and the signals obtained at the outputs of stroke "ke are timing charts for explaining the method nltsie. Let the source be a sinusoidal signal 1 with a frequency of 5l-1t; / T (diagram 1), which then converts the signal into a sequence of unipolar low-frequency pulses (diagrams 2, 3); Then, from signals 2 and 3, four signals 4–7 are received (diagrams 4–7), which are unipolar pulse sequences with an imputas ratio of 4 times the duration.

readings of these signals are shifted from the distance to; source harmonic signal respectively

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From signal 4, a sequence of Pf bundles consisting of N / 2 high-frequency pulses is obtained, in conjunction with S5 (diagram 8).

branch times and times.

Claims (2)

By combining the results of reading from both channels according to the conditions, the summation of the ICs with the pulses shown in diagram 17, which correspond to the values of (+ l) jr, we obtain zero values (diagram 18) that are T / 4 B1I apart. Signals 5 and 6 are also converted to B: sequences of packs p, and p. Consisting of M high frequency pulses (diagrams 9, 10), and a single signal is obtained from signal 7 at the time of decay; (diagram 11). Carried out on the packs p, p, p of the operation of subtraction and summation, starting from the zero moment of time, on .S we get. P p -. oh These operations are performed during 2T. The result of the first operation will be negative, and the second - positive. Therefore, the graphical dependence of the number of pulses on time during the interval from 0 to 2T will look like that shown in diagram 12 (solid line), from which it can be seen that during a time equal to two periods , this number takes the value three times zero. The time points to which these values correspond will be O, J-t T If now at the moment 2T you instantly erase the result using a pulse (diagram 11) from the trailing edge of signal 7 and repeat the procedure described in subsequent time intervals multiples of 4 n (M -I, 2,3 ....), then null marks 6j will occur, respectively, at moments of amt, (2) and- |) t. (It is worth noting that, for some reason, the frequency O ., respectively, the number N will also change and, thus, up to a value equal to the difference of two adjacent periods, b The zero marks will also be tackled by performing a similar manipulation on a separate channel, but with a time shift by the value of T, with the Pg-, Rb 1 pulses represented in diagrams 13, 14, 15 and received from signals 6, 7, 4, respectively. the result of which is erased with impesions (diagram 16), we will have zero marks in the second channel (diagram 12, dashed line) in accordance with the application of the proposed method allows for a complex spectral analysis in a wide frequency range. In particular, compared to the known By systems, the frequency range is expanded by about three orders of magnitude. The speed of the method for batch processes is determined by a value not exceeding the time of two periods, and the accuracy of the method is determined by the ratio of the frequency of the filling pulses to the frequency of the process under study. The invention of the method of forming orthogonal rectangular signals, in which rectangular pulses are formed separately for the direct and inverse values of the one-period periodic oscillation and the resulting high-frequency impulse time intervals are completed, in order to increase accuracy and expand the frequency band. , for a time interval of four periods, four low-frequency pulses of the same duration are formed, in which the leading edge of each of the latter coincides with the trailing edge m pre-. First, for a single channel, the first low-frequency pulse is converted into a bundle consisting of M high-frequency pulses, the second and third are converted into similar bundles consisting of H3N high-frequency pulses, then the number N corresponding to the second bundle is subtracted from N / 2 and the resulting the result is summed up with the number M corresponding to the third bundle, after which the result of the fourth front-channel low-frequency moment is obtained, then it is erased, whereas in the second channel the described actions are are shifted in time equal to two periods of the input copebi, given 8 signals in response. Zero results of subtraction in summation on both channels and summation of signals with signals corresponding to the beginning of each even period, and repeating the specified results, receive the output signals. signals. Sources of information taken into account in the examination 1. Aleksenko, 1A. G., Ko ombet E.A. Starodub G. I, Application of analogue prezisoria. Inetal schemes. M., Tadio, Communication, 1981, pp. 202-203. 2. Schruniggein V. Phaser, tJ6cTt tachy and double frequency and trigger. Electronics, N ° 21, 1976, vol. 40, p. 59-60.