SU802913A1 - Method of determing repetition period of arbitrarily-modulated pulse trains - Google Patents

Description

The invention relates to measuring equipment and is intended to measure the sequence of telemetric signals.

Known method for determining peri- ³ ode pulse repetition based on the principle S1J time selection.

However, with this method, a large measurement time period is required and it is applicable only to determine the pulse repetition period inside a packet of AND pulses, provided that the pulses follow at regular intervals.

The purpose of the invention is the reduction of time — 15 times the determination of the period.

This is achieved by successive selection of the pulse sequence until conditions are obtained when all pulses in series — 20 tm — satisfy the periodicity conditions.

In FIG. 1 is a timing chart illustrating a sequence selection process; on <

FIG. 2 is a block diagram of a device that implements the specified method.

The device consists of forming a pulse sequence C _in (O, pause blanking and pause measurement circuit 2, register 3 for recording time interval codes, circuit 4, 5 for comparing codes, and circuit 6 for determining the true period.

A device that implements the method operates as follows.

At the input of the shaper 1, a pulse sequence C ₀ (t) with an unknown repetition period T _o , as well as a clock frequency f _T necessary for measuring the intervals, is received.

Shaper 1 produces the formation of a pulse sequence (t) with pulses of the same duration. In scheme 2, the blanking of pulses of the sequence Cq (t) and the measurement of the pauses of the resulting new sequence occur. At the initial moment of time, 0 is written in register 3, and with the arrival of the pulse sequence Cg (t) ^ the first measured pause value through codes comparison 4, 5 is written in register 3. The second pause T _a 'of the sequence C _o (t) will already be expand due to ^ blanking of pulses, if Vj, or correspond in register 3, if. In the general case, if the inequality T; 'is satisfied, the process of expanding the blanking interval will proceed. When T '= at the output (d) of the code comparison circuit 5, a signal appears that measures the distances between the nearest opposite edges of the first pulses of the sequence C ό (t) located in adjacent pauses of the sequence (t). If T; <c, then the value of C is recorded in register 3, the measurement of the values of t stops and the subsequent blanking of the sequence C _o (t) is carried out by the value of c. If ~ ^ 2> then the signal at the output (d) of the code comparison circuit 5 transfers circuit 6 to measure the distances between the nearest opposite edges of the second pulses tj of the sequence Cq (t) located in adjacent pauses of the sequence Cj, (t). In the general case, always, if tj>T;, the value of tj is written into register 3 and the circuit 6 for determining the true period returns to its original state. If tj / Тj, then circuit 6 measures the distances tj + i between the following pulses of the sequence C © (t) falling into the intervals of the sequence C <(t). If t; -Tj for all j = 1,2, ..., w = η-l, where m is the h ^ layer of pulses of the sequence C _o (t) located in adjacent pauses of the sequence C i (t), then the process of determining the period T _o sequence C _o (t) is complete.

Compared with the known methods based on the method of temporary selection, the proposed method has universality, requires low hardware costs.

Claims (1)

proceed with the process of expanding the blanquiour interval. When TD TD, in the code (d) of the code comparison circuit 5, a signal appears that measures the distance between the nearest opposite edges of the first pulses of the sequence Co (t) located in the adjacent pauses of sequence C (t). If T, - t, then the value of t is written to register 3, the measurement of the values of t is prevented, and the subsequent blanking of the sequence Cq (t) is carried out by the value of t. If t and then the output signal (d) of the code comparison circuit 5 transfers the circuit b to measure the distance between the nearest opposite edges of the second pulses tj of the sequence CQ (t) located in the adjacent pauses of the sequence C4, (t) if tj Ti, the value of tj is rewritten to register 3 and the true period determination circuit 6 returns to the initial state. . If tj / Tj /, then scheme b measures the distances tj + between the following pulses of the sequence Co (t) falling in intervals g of the sequence C (t). If tj -Tj for all j 1,2, ..., m n-1, where m is Q1 | layer of pulses of the sequence CQ (t) that are in the adjacent pauses of the sequence С I (t), then the process is determined1 of the TO period the sequence C o (t) is complete. Compared with the known methods based on the method of temporarily selection, the proposed method is versatile, requires little hardware costs. Claims The method of determining the repetition period of an arbitrarily modulated pulse sequence based on multiple selection of maximum pauses, characterized in that, in order to shorten the period definition time, the pulses of the original sequence are shortened before a pulse sequence equal to the duration is obtained, sequential blanking of the pulses of the resulting sequence is performed, starting with the first pause by an amount equal to the pause resulting from the previous b Anchoring, before obtaining a uniform pulse sequence, determines the frequency of the pulses of the original sequence, falls into the intervals of a uniform pulse sequence, and if the conditions of the periodicity are violated, increase the blanking interval until all the pulses of the initial sequence that fall into the intervals of a uniform sequence are satisfied conditions of periodicity. Sources of information taken into account in the examination 1. USSR author's certificate 414565, cl. G 04 f Yu / GS, 1973. fL Jt Tl SI Jl Alu / fr