SU838662A2 - Pulse signal time position meter - Google Patents

Description

The invention relates to a radio measuring technique, in particular to devices for measuring the time of appearance of pulse signals of arbitrary shape.

According to the main author. St. No. 454531, a measuring instrument for the temporal position of pulsed signals at their center of gravity is known, comprising a cascade of damping, oscillations, and a video signal generating unit, a threshold cascade, a shock oscillating link, a null indicator cascade, and a digital measuring unit, the damping oscillation cascade 15 being connected to a shock oscillatory link [1].

However, with a finite period of forced oscillations of the shock oscillatory link, a 20 error in measuring the position of the video signal occurs, the magnitude of which depends on the shape of the video signal and cannot be taken into account in this meter.

The aim of the invention is to increase the accuracy of measuring the vertical position of video pulses of arbitrary shape.

This goal is achieved by the fact that in the measuring device of the temporary position of the pulse signals, comprising a damping oscillation cascade and a series-connected video signal generating unit, a threshold cascade, an oscillatory shock link, a zero-indicator cascade and a digital measuring unit, the output of each damping oscillation being connected to the second input of the shock oscillatory link, additionally introduced a digital meter of the difference in time moments of zero transitions, series-connected buffer cascade, shock oscillator link and a zero-indicator cascade, as well as a damping oscillation cascade, the output of which is connected to the second input of the additional shock oscillatory link, the input of the buffer cascade is connected to the input of the main shock oscillatory link, and the output of the additional zero-indicator cascade is connected to the first input of the digital meter the difference in time intervals of zero transitions, the second input of which is connected to the first input of the digital measuring unit, the second input of which is connected to the output of the digital difference meter in Yemen moments of zero-crossings.

The drawing shows a structural diagram of a meter for the temporary position of pulse signals.

The measuring instrument of the temporary position of the pulse signals comprises a pulse signal generating unit 1, a threshold stage 2, a buffer stage 3, a main stage 4 for damping the oscillation, a main shock oscillating element 5, an additional shock oscillating element 6, an additional oscillation damping stage 7, the main zero-indicator stage 8, additional null indicator stage 9, a digital meter 10 of the difference in time moments of zero transitions and a digital measuring unit 11.

The meter works as follows.

The pulse input signal is generated by the pulse signal generating unit 1 and through the threshold cascade 2 it is supplied to the shock oscillating Link 5 and to the buffer cascade 3, from the output of which the signal is received by the unstressed oscillating link 6. Boo., The trimming cascade 3 serves as a decoupling element between the shock - oscillatory links 5 and 6. Forced vibrations from the outputs of the shock vibrational links 5 and 6 go respectively to the inputs of the zero-indicator cascades. 8 and 9, in which the moments of the transition through ny fluctuations. Moreover, due to the finiteness of the periods T and forced oscillations, the moment of their first transition through zero t ₀ ^ and t οί differs from the exact position of the center of gravity of the video pulse by time,!, Determined by the sum of a quarter of the period of forced oscillations and the error it and it 2 ^, from - due to the asymmetry of the shape of the video pulse relative to its center of gravity.

In accordance with this, the exact value of the center of gravity of the video pulse is determined as follows 4τ ⁼ ί οΐ 4 ^T '~ ⁼ T7 ^t 2.-d ^1: g ( ¹ )

The magnitude of the error in measuring the temporary position of the center of gravity and δϊ ₂ depends both on the shape of the video pulse and on the period of forced oscillations and T ₂ , and the longer the period, the smaller the error.

From (1), we can obtain AtΔΛ. ₍ = ~ ~ (Chi too.)

Having chosen such a relation between the periods of forced oscillations of the vibrational links 5 and 6, so that the condition = 2 is fulfilled, one can easily find the error of measurement of time. the change in the position of the center of gravity of the video pulse due to the asymmetry of its shape relative to its center of gravity = i ^f > ^T <- ^t 2) ·· ^ - t _o -z) (2)

From the outputs of the null indicator stages 8 and 9, the selected moments of the forced oscillations passing through zero are fed to the inputs of the digital meter 1 of the difference in time moments of zero transitions 10, in which the time interval ^t cH ~ ^t o2 is measured. · The measured difference of time moments of zero transitions t _oi -t _o2, for example in digital form is supplied to the digital measuring unit 11, wherein the formula (2) is the measurement error of temporal center of gravity position of a video, and in the formula (1) is determined by current temporal position Centralized severity of a video.

Thus, by choosing the appropriate ratio between the periods of forced oscillations of the shock vibrational links 5 and 6, the error of measuring the temporary position of the center of gravity of the video pulse is eliminated due to the asymmetry of its shape relative to its center of gravity.

As a result, the period of forced oscillations of the shock vibrational link is reduced, which makes it possible to measure the temporal position of video pulses that follow with a higher repetition rate, reduce the dimensions and weight of the shock vibrational link, especially in the case of measuring the temporal position of the center of gravity of long (more than 500 μs) video pulses.

Claims (1)

1. USSR author's certificate 4545.31, cl. G 04 F 11/08, 1974.