SU1265671A1 - Method of seismograph operative calibration - Google Patents

Abstract

The invention relates to the field of seismometric equipment and can be used in the operational calibration of a seismograph. The purpose of the invention is to verify the accuracy of the calibration. In the method, the excitation effect is supplied as a sum of sinusoidal currents of several frequencies, the amplitudes of which are set proportionally to the squares of their frequencies. Amplitude Frequency Response: Calculate ONLY at the supplied frequencies. I 3. apt. 1 il. from 5 W

Description

The invention relates to seismometry and can also be used in engineering seismology and seismic prospecting. The aim of the invention is to increase the calibration accuracy. The drawing shows a calibration scheme that implements the proposed method. The calibration circuit consists of generators 1-3, the outputs 4-6 of which are respectively connected via scaling resistors 7-9 with an adder 10 built on the operational amplifier, with its subtractive input 11. Mass resistor 12 is connected between the output 13 and the operational input 11. booster. The output of the adder is connected to a calibrating channel 14, consisting of a seismometer 15 with a calibration 16 and a working 17 windings, an amplifier 18 and a recorder 19. At that, the calibration winding of the seismometer is connected to the output of the adder, and the working one through an amplifier - with a recorder. The calibration scheme works as follows. The frequencies of generators 1-3 are chosen so that the highest frequency itself corresponds to the upper boundary frequency of the seismograph, each subsequent frequency is lower than the previous one, for example, B twice, and the lowest frequency itself is equal to or less than the boundary frequency of the seismograph. Justification of the choice of schaga often. The spectrum of a sinusoid consisting of π-periods, where n is an integer, is determined by the formula - Cl) sin (JLf / foJ 2 "D1- (Y / Y). For a sufficiently large number of periods, the main maximum of the spectrum S lies at frequency f. This spectrum has lower frequencies, d, i.e., at, for such p, than f. When n / p is an integer and the sine in the numerator refers to O. In this case, if the original sinusoid frequency fp add a sinusoid with often that fo / p and the number of periods n / p, then the main maximum of the spectrum of the added sinusoid falls on the O spectrum of the first sinusoid and therefore does not contain m error, and the main maximum of the spectrum of the first sinusoid falls on the spectrum of the added sinusoid and also does not contain the error, i.e. the orthogonality condition is met. If the working frequency range of the seismic channel overlaps r frequencies with equal frequency division factors p, has the form p / p (where K is an integer and OiKir). In this case, the main maximum of the spectrum of each of the sinusoids occurs on the zeros of the spectra of the remaining sinusoids. In principle, the condition of orthogonality is fulfilled for any, even a number of periods, n, ° C, which need to be registered when calibrating the channel, goes beyond or generally goes to infinity. If p is an integer, then the required η is much smaller and its required value is determined by the ratio of the upper and lower limiting frequencies of the working part of the channel frequency range ot fg / fH and the required number of periods in the calibration signal recording to f, so that the sinusoid spectrum is Dossfade with- f.,. A good enough neck coincidence is provided at 10-12 periods (deviation of more than 0.15% in frequency and an error in the determination of 3 -0.04%). To reduce the length of the calibration signal, the frequency division factor p must be chosen with a number. However, if more, it turns out to be rare. a frequency grid that may not be enough to control the frequency response of the channels, especially not very broadband. With most channels, it is calibrated with 5-6 frequencies, which is quite enough for the effective (|) effective operational control of the frequency response. The amplitude of the current at each of the supplied frequencies set using resistors 7-9 is proportional to the square of the frequency. The total scale factor of the pulse using the calculation or experimentally selected so that the response of the seismograph occupied approximately 0.75-0.85 dynamic range of the recorder, and set using a resistor 12. To ensure calibration accuracy 1-2% required response recording time is set to 10 -12 periods of the lowest frequency sinusoid, in

Claims (2)

Claim 1. The method of on-line calibration of a seismograph consisting of a seismometer and a recorder, which consists in applying a single exciting action in the form of an electric current to the calibration winding of the seismometer and measuring the response of the amplitude-frequency characteristic, characterized in that, in order to increase the accuracy of calibration, the exciting effect is applied in the form of the sum of sinusoidal currents of various frequencies of finite amplitude, while the amplitudes of sinusoidal currents are set in proportion to the squares of their frequencies and amplitudes tudno-frequency characteristic is measured only at frequencies supplied. 2, The method of π. 1, it is distinguished by the fact that the highest frequency in the exciting action corresponds to the upper boundary frequency of the seismograph, each subsequent frequency is integer lower than the previous ^{one by a} factor of ¹ , and the lowest frequency is not greater than the lower boundary frequency of the seismic: mografa.