SU949579A1 - Seismic vibrator control signal generator - Google Patents

Description

The invention relates to seismic exploration, and in particular to control devices for one or a group of vibrational sources of seismic signals, and can be used in geophysical exploration both on land and at sea.

A device for generating control signals for seismic vibrators is known, designed to produce quasi-sinusoidal oscillations with a continuous linear increase or decrease in frequency. In this device, a parallel series of numbers generated by the counter is supplied to the parallel inputs of the adder. The overflow of the adder is a sequence of pulses, the frequency of which increases linearly or decreases in a given time interval. These pulses are converted into sinusoidal oscillations. with increasing or decreasing frequency, which are supplied to the control inputs of the actuator of the seismic vibrator £ 0 ·

However, the device has insufficient functionality.

Closest to the proposed one is a generator of control signals for seismic vibrators containing a clock pulse generator, the output of which, on the one hand, is connected through the main frequency converter to the input of the pulse sequence converter into a harmonic function and, on the other hand, to the counting input of a controlled frequency divider , a reversible clock counter, the code output of which is bitwise connected to the control inputs of the main frequency converter, an auxiliary converter frequency divider, frequency subtraction circuit, switch and frequency comparison circuit, as well as registers for entering the duration of the scanning of the boundary frequencies of the operating range, the auxiliary frequency converter is connected between the counting input of the indicated reverse counter and the control output of the frequency divider, the control inputs of which are bitwise connected to the outputs registers of the duration of the scan, the control inputs of the specified auxiliary frequency converter bitwise connected to the output of the subtraction circuit h stot to which inputs., as well as a switch connected registers boundary frequencies.

In this device, the oscillations of the clock crystal oscillator by a digital converter are converted into a pulse sequence with a linear increase or decrease in frequency. This sequence is further converted into sinusoidal oscillations. To control the converter, a reversible counter is used, at the input of which a certain frequency of pulses is supplied during a given time interval. This frequency of pulses and the mode of operation of the counter determines the speed and direction of change of the output numerical values of the counter, which are fed to the main converter.

Reverse counter operation mode. (i.e., the initial and ’final values of the output number, increasing or decreasing numbers at the output, the rate of such a change) is set unchanged for the entire cycle of the vibrator. The device allows you to change the boundary frequencies, sweep speed, respectively, to regulate the frequency spectrum of oscillations excited by a seismic vibrator [2 ^].

However, without a sharp decrease in the productivity of field work with the known device, it is impossible to excite oscillations in the earth with a precisely defined spectrum and weaken the correlation noise. In order to achieve such goals, in the intervals between source operation cycles accumulated at the same excitation point, it is necessary to rebuild the source generators and seismic stations, which reduces the productivity of the seismic profile.

The purpose of the invention is the expansion of the functionality of the signal generator control seismic vibrators.

This goal is achieved by the fact that the signal generator control seismic vibrators containing a clock pulse generator, the output of which, on the one hand, is connected through the main frequency converter to the input of the pulse sequence converter into a harmonic function and, on the other hand, to the counting input of the controlled one. a frequency healer, a reversible clock counter, whose code output is bitwise connected to the control inputs of the main frequency converter, Auxiliary conversion a frequency generator, a frequency subtraction circuit, a switch and a frequency comparison circuit, as well as registers for inputting the scan time, the operating frequency boundary frequencies, the auxiliary frequency converter being connected between the counting input of the indicated reverse counter and the output of the controlled frequency divider, the control inputs of which are bitwise connected to the outputs of the scan duration registers, the control inputs of the specified auxiliary frequency converter are bitwise connected to the output of the subtraction circuit from, to the inputs of which, as well as the switch, registers of boundary frequencies are connected, registers of intermediate frequencies and the duration of the scan intervals are introduced, schemes for comparing intermediate frequencies, a counter of the number of frequency matches, a switching circuit, while the first inputs of the frequency comparison circuit are bitwise connected to the outputs of the reversible counter and the second inputs of the frequency comparison circuit are connected to the outputs of the frequency registers and the inputs of the frequency subtraction circuit, the outputs of the frequency comparison circuit are connected to the input of the counter of the number of frequency matches, whose outputs (except the last one operating under the program) are connected to the inputs of the scan duration registers and the inputs of the switching circuit, the outputs of which are connected to the inputs of the frequency setting registers, and the reset buses are connected to the frequency comparison circuits ^ through the counter of the number of frequency matches and the switching circuit.

Figure 1 shows a schematic block diagram of a signal generator scan; figure 2 is a schematic diagram of a switching unit; on Fig. Graphs of the dependence of changes in the frequency of oscillations from time to time in known devices (a) and in the proposed device (b).

The vibrator control signal generator comprises a clock pulse generator 1, the output of which, on the one hand, through the main frequency converter 2, is connected to the input of the pulse converter 3 in a harmonic function and, on the other hand, to the counting input of a controlled frequency divider 4, a counter 5 clock pulses, the code output of which is bitwise connected to the control inputs of the main frequency converter 2. Between the counting input of the reversible counter 5 and the output of the controlled frequency divider 4, an auxiliary frequency converter 6 is included, the control inputs of which are bitwise connected to the code output ": a frequency subtraction circuit 7, which is also connected to the sign input of the counter 5. The control inputs of the divider 4 are bitwise connected to code outputs registers 8-18 setting the duration of the scan.

The outputs of the installation registers of the initial 19, intermediate 20-29, and final 30 frequencies, respectively, are connected to the inputs of the registers of the frequency subtraction circuit 7, the switch circuit 31, and the frequency comparison circuit 32-43. The code output of the switch 31 is bitwise connected to the installation inputs of the counter ^ 5. The second code inputs of the frequency comparison circuits 32-43 are connected together and connected to the output of the counter 5. The pulse outputs of the comparison circuits are parallelized and connected to the input of the counter 44 frequency matches. Its outputs are connected to the inputs of switch 31, switching circuit 45, and registers 8-18.

The switching unit 45 contains (Fig. 2) the inputs to which the outputs of the counter 44 for the number of frequency matches, the diode distributor 46, the switch 47 for the number of used sweep sections, the outputs 19-30 connected to the corresponding frequency setting registers, and the output are reset ' ¹ , connected to all bus return circuits.

Fig. 3 shows graphs of the frequency f of oscillations versus time t. Dependence a is a linear law of frequency change over the entire time interval of the oscillation excitation cycle. Dependence b also displays a linear change in frequency over time. But the frequency interval from the initial f _H to the final f _K frequencies is divided into three sections: with a low rate of increase, with a high rate of decrease and low speed, increase. These three sections in time are separated by two intervals, within which there are no oscillations. Due to a decrease in the sweep speed in the first and last intervals and an increase in the sweep speed in the middle interval, the optimal frequency response of the waves excited in the ground is obtained. By introducing gaps between the three sections of the oscillations, the correlation noise is reduced. 55

The operation of the generator is as follows.

Before starting the generator, the scan parameters are set: the duration T of the selected sections (on registers 8-18), the boundary frequencies of the boundaries of these sections (on registers 19-30) and the number m of sections (on switch 47). For the example shown in figure 1 scan T _x = 0s;

T ₄ = 3s; T ^ = 0s; T ₆ = 3s;

T ₉ = 0s; T | ₀ = 3c; T _n = 0s;

Hz; f 5 = 25. ru; f ₄ = 0 Hz; f ₇ = 0 Hz;

, - f | ₀ = 90 Hz; 0 Hz; w = 11

T ₂ = 0s; T ₅ = 0s; T ₇ = 0s; T ₈ = 3s; f4 = 0 rn; f ₂ = 15 f ₅ = 90 Hz; f ₆ = 25 Hz; f _e = 0 Hz; f ₉ = 0 Hz f ₍₁ = 110 Hz; f _{| 2} = 0 Hz; w = 11. Moreover, Ί \ = T is the total duration of the sweep. In the general case, T + dd t, / 0.

The signal '' Start ¹ '', which can be applied either by the vibrator operator, for example, using a button, or from an external synchronizing device, for example via a communication channel from a seismic station '(not shown), sets the number Н £ in counter 5 ^ corresponding to the frequency f4, and at the output of the generator 1, clock pulses with a frequency fe appear. Clock pulses are fed to a divider control input 4 and at the output of the last pulses occur with a frequency of ² · jj, where N <- numerical value of duration T ₄ of the first scanning interval set in the register 8.

The frequency of the output pulses of the divider 4 input to the input of the converter 6 is converted to another constant frequency, the value of which, as in the main frequency converter 2, is linearly dependent on the number N supplied to its control inputs. This number is obtained as the difference N = Nf ₂ -N £, where Νί <and N £ _{2 are} numbers corresponding to the values of the frequencies f ₁ and f ₂ , and is generated by the frequency subtraction circuit 7. Consequently, the output of converter 6 is supplied to the input of counter 5 by pulses of frequency _F _fo, (N ^ -Nf-,) Ν ₊ · where n ₆ is the number of binary bits in converter 6. To the sign input of counter 5 from the output of frequency subtraction circuit 7 the inequality code f ₂ -f ₄ > 0 or f ₂ - f ^ O is passed. Depending on this, the numerical content of counter 5, starting from the moment `` Starts up (+) or decreases (-) according to law (1), according to which the frequency f _{o of} clock pulses arriving at the input of the main converter 2, is converted last into the frequency where η is the number of binary digits in the Converter 2.

From the expression (3) shows that the output of the Converter 2 frequency

Ί of pulses increases linearly or decreases with a speed equal to —fl—, - (Nb-Nb) 2 ^π ι ^4η 6. N <

(4)

At the moment when the numerical content of the counter 5 reaches the value, the frequency comparison circuit 32 gives out a pulse, under the influence of which the voltage at the first output of the counter 44 vanishes, and a signal appears at the second output. Registers 8 and 19 are turned off, and operating states are set in registers 9, 20 and 21, which changes the sweep speed from value (4) to a new value of 15 fo Nb-Nfj

2 ⁿ 2 ^{+ n} ₆ N ₂ ' ⁽⁵⁾ where N | ₂ - the number corresponding to the value of the frequency f ^; N _z - corresponds to the duration T _{2 of the} second interval - 20 la sweep.

Similarly, the circuit switches to the following sweep intervals. At the end of the last sweep interval, the signal from counter 25 is supplied to the reset output of the switch block and the entire circuit returns to its initial state. The output pulses of the main transducer 2 by the transducer 3 rear are converted into a harmonic signal with pulse-width or amplitude modulation, which is then fed to the input of the electromechanical transducer of a vibration source 35 (not shown).

The proposed device provides wide possibilities for varying the characteristics of elastic waves excited in the earth while optimizing them according to the criterion for matching the source with the geological environment and allows us to achieve a significant attenuation of correlation noise in the vibrational seismic reverb method.

on the other hand, to the counting input of a controlled frequency divider, a reversible clock counter, the code output of which is bitwise connected to the control inputs of the main frequency converter, auxiliary frequency converter, frequency subtraction circuit, switch and frequency comparison circuit, as well as registers for input, sweep duration , the boundary frequencies of the working range, and the auxiliary frequency converter is connected between the counting input of the specified reverse counter and the output of the controlled divides A frequency control inputs of which are connected bitwise with the outputs of the registers scan duration, the control inputs of said auxiliary inverter connected to the output bitwise frequency subtraction circuit to inputs of which, as well as a switch connected registers boundary frequencies from. having in mind that, in order to expand the functionality, intermediate frequency registers and durations of scanning intervals, intermediate frequency comparison circuits, a counter of the number of frequency coincidences, a switching circuit are introduced into it, while the first inputs of the frequency comparison circuit are bitwise connected to the outputs of the reversible counter and the second inputs of the frequency comparison circuit are connected to the outputs of the frequency registers and the inputs of the frequency subtraction circuit, the outputs of the frequency comparison circuit are connected to the input of the counter of the number of frequency matches, the outputs otorrhea connected to inputs of the registers scan duration and the inputs of the switching circuit, the outputs of which are connected to the inputs of the frequency setting register and a reset bus connected to the comparator circuit via a frequency counter pure

Claims (2)

The invention relates to seismic exploration, namely, control devices for one or a group of vibration sources of seismic signals, and. Can be used in geophysical prospecting both on land and at sea. A device for generating seismic vibrator control signals is known, which is designed to obtain quasi-sinusoidal oscillations with a continuous linear increase or decrease in frequency. In this device, a series of numbers is generated by parallel counter outputs on the parallel inputs of the adder. Overflow of the adder is a sequence of pulses whose frequency rises or decreases linearly at a given time interval. These pulses are converted into sinusoidal oscillations. with increasing or decreasing frequency that arrive at the control inputs of the actuator of the seismic vibrator l. However, the device has insufficient functional capabilities. Closest to the present invention is a seismic vibrator control signal generator containing a clock pulse generator, the output of which, on the one hand, is connected to the input of a pulse sequence converter to a harmonic function through the main frequency converter and, on the other hand, to a counting input of a controlled divider frequency, reversible clock counter, the code output of which is bitwise connected to the control inputs of the main frequency converter, an auxiliary input a frequency former, a frequency subtraction circuit, a switch and a frequency comparison circuit, as well as registers for entering the sweep duration of the working frequency boundary frequencies, with an auxiliary frequency converter connected between the counting input of the specified reversing counter and the control output of the frequency divider, which are connected one by one with the outputs of the sweep duration registers, the control inputs of the specified auxiliary frequency converter are bitwise connected to the output of the circuit read out and frequencies, to the inputs of which., as well as the switch are connected frequency limit registers. In this device, oscillations of a clock crystal oscillator. A digital converter is converted into a pulse sequence with a linear increase or decrease in frequency. This sequence is further converted to sine wave oscillations. To control the transducer, a reverse counter is applied, to the input of which a certain frequency of pulses is given for a given time interval. This pulse frequency and the operating mode of the counter determine the speed and direction of change of the output numerical values of the counter, which are fed to the main converter. Mode of operation of the reverse counter. (i.e., the initial and final values of the output number, the increase or decrease of the numbers at the output, the rate of such a change) is set unchanged for the entire cycle of operation of the vibrator. The device allows changing the boundary frequencies, the sweep speed, and, accordingly, adjust the frequency spectrum of oscillations excited by the seismic vibrator 2j. However, without a sharp decrease in the productivity of field work with a known device, it is impossible to generate oscillations with a precisely specified spectrum and attenuation of correlation noise in the ground. In order to achieve such goals, in intervals between the source operation cycles accumulated at one excitation point, it is necessary to rebuild the source generators and the seismic stations, which reduces the productivity of the seismic profile. The purpose of the invention is to extend the functionality of the generator of control signals for seismic vibrators. The goal is achieved by the fact that the seismic vibrator control signal generator, containing a clock pulse generator, the output of which, on the one hand, is connected through the main frequency converter to the input of the pulse sequence to a harmonic function and, on the other hand, to the counting input of the controlled A frequency unit, a reversible counter of clock pulses, the code output of which is bitwise connected to the control inputs of a 1-phase frequency converter, an auxiliary transducer a frequency converter, a frequency subtraction scheme, a switch and a frequency comparison circuit, as well as registers for input, scan duration, frequency cutoff frequencies, and an auxiliary frequency converter is connected between the counting input of the specified reversing counter and the output of the controlled frequency divider, controlling the inputs of which are bitwise connected to the outputs of the sweep duration registers, the control inputs of the specified auxiliary frequency converter are bitwise connected to the output of the frequency subtraction circuit the one to which the inputs and the switch are connected to the boundary frequency registers, the intermediate frequency and sweep intervals, the frequency comparison comparison circuit, the frequency coincidence counter, the switching circuit are entered, the first inputs of the frequency comparison circuit are connected to the reverse counter outputs , and the second inputs of the frequency comparison circuit are connected to the outputs of the frequency registers and the inputs of the frequency subtraction circuit, the outputs of the frequency comparison circuits are connected to the input of the counter for the number of matches The outputs whose outputs (except the last one operating under the program) are connected to the inputs of the sweep duration registers and the inputs of the switching circuit, whose outputs are connected to the inputs of the frequency setting registers, and the reset buses are connected to frequency comparison circuits: through a counter of the number of frequency matches and the switching circuit. Fig. 1 is a schematic block diagram of a scan signal generator; 2 is a circuit diagram of a switching unit; Fig. The graphs of the dependence of the change in the oscillation frequency on the time in known devices (a) and in the proposed device (b). The oscillator control signal generator contains a clock pulse generator 1, the output of which, on the one hand, through the main frequency converter 2, is connected to the input of the converter 3 of the pulse sequence into a harmonic function and, on the other hand, to the counting input of the controlled frequency divider 4, a reversible counter 5 clock pulses, the code output of which is serially connected to the control inputs of the main frequency converter 2. An auxiliary frequency converter 6 is connected between the counting input of the reversible counter 5 and the output frequency control divider 4, the control inputs of which are bitwise connected to the output terminal of the frequency subtraction circuit 7, which is also connected to the sign input of the counter 5. The control inputs of the divider 4 are digits the bottom is connected to the code outputs of registers 8–18 of the unwinding length. The outputs of the setup registers of the start 19, intermediate 20-29, and end 30 frequencies are respectively connected to the inputs of the registers of the frequency subtraction circuit 7, the circuit 31 of the switch, and the frequency comparison circuits 32-43. The code output of the switching bodies 31 is bit-wise connected to the installation inputs of counter 5. The second code inputs of the frequency comparison circuits 32-43 are connected together and connected to the output of the counter 5. The pulse outputs of the comparison circuits are paralleled and connected to the input of the counter 44 frequency drops. Its outputs are connected to the inputs of the switch 31, the switching circuit 45 and the registers 8-18. Switching unit 45 contains (FIG. 2) the inputs, to which the outputs of the counter 44 of the number of frequency matches, the diode distributor 46, the switch 47 of the number of used sweep sections, the outputs 19-30 connected to the corresponding frequency setting registers, and the Reset output, are connected. connected to all tires of reset schemes. Fig. 3 shows graphs of the oscillation frequency f as a function of time t. The dependence of a is the linear law of frequency variation over the entire time interval of the oscillation excitation cycle. Dependence b also displays a linear in time frequency change. But the frequency range from the initial f to the final f frequencies is divided into three sections: with a small rate of increase, with a large rate of decrease, and a small rate of increase. These three areas are separated in time by two intervals, within which there are no oscillations. By reducing the sweep speed in the first and last intervals and increasing the sweep speed in the middle interval, the frequency response of the waves excited in the earth is optimal. By introducing gaps between the three oscillation patterns, the correlation interference is reduced. The generator operates as follows. Before starting the generator, the sweep parameters are set: the duration T of the selected sections (in registers 8-18), the boundary frequencies f of the boundaries of these sections (in registers 19-30) and the number m of sections (on switch 47). For the example of T 1 shown in Fig. 1, T; Hz; Hz; f. Hz; f4 0 Hz; Hz; Hz; 7- O Hz; fe O Hz; fg O Hz; f, o 90 Hz f ,, 110 Hz; f | 2 O Hz; . At the same time the full sweep duration. In general, T4D5, 7, 9.4. By the Start signal, which can be sent both by the vibrator operator, for example, using a button, and from an external clock device, for example, via a communication channel from a seismic station (not shown), the the counter 5 of the number H, corresponding to the frequency f4, and at the output of the generator 1, clock pulses with a frequency fp appear. The clock pulses arrive at the input of the controlled divider 4, and at the input of the latter there appear the pulses fo, where N is the numerical value with frequency of the duration T of the first sweep interval, set in register 8. The frequency of the output pulses of the divider 4 arriving at the input of converter b, is converted to another constant frequency, the value of which, as in the main frequency converter 2, is linearly dependent on the number N supplied to its control inputs. This number is obtained as the difference N Nij-N i, where Nf, and N i2 numbers with the corresponding values of the frequencies f and f, and are generated by the frequency subtraction circuit 7. Therefore, the output of the Converter 6 to the input of the counter 5 receives pulses with a frequency. (,) 2 N. where n is the number of binary bits in the converter 6. The inequality code f..Q or is transmitted to the sign input of the counter 5 from the output of the frequency subtraction circuit 7. Depending on this, the numerical content of counter 5, starting from the moment of Start, increases (+) or decreases (-) according to the law fo (Nb-NtO. ,, ,,, in accordance with which the frequency f, of clock pulses arriving at the input of converter 2 is the last to be converted to frequency lNi, tu. yi ::. Ki + 1 b2 N where n is the number of binary bits in converter 2. From expression (3) it is seen that at the output of converter 2 the frequency of pulses increases or decreases linearly with speed equal to. (N {aN {) N At the moment when the numerical content of counter 5 reaches the value of Nf, the circuit is 32 frequency output produces a pulse, under which the voltage at the first output of counter 44 vanishes, and a signal appears at the second output. Registers 8 and 19 are turned off, and operating states are set in registers 9, 20 and 21, which change There is no sweep speed from value (4) to the new value fo Nb-Nf2 where O. is the number corresponding to the frequency fj; Nj corresponds to the duration Tj of the second sweep interval. Similarly, the circuit switches to the next sweep intervals. At the end of the last sweep interval, the signal from the counter 44 is fed to the waste output of the switch unit and the whole circuit returns to the initial state. The output pulses of the main converter 2 by the converter 3 are converted into a harmonic signal with a pulse-width or amplitude modulation, which is then fed to the input of an electromechanical converter of a vibration source (not shown). The proposed device provides wide possibilities for varying the characteristics of elastic waves excited in the ground while optimizing them according to the criterion of matching the source with the geological environment and allows achieving a significant attenuation of the correlation noise in the vibration method of seismic sweep. Invention The generator of control signals for seismic vibrators containing a clock pulse generator which, on the one hand, through the main frequency converter is connected to the input of the converter pulse sequence into a harmonic function and, on the other hand, to the counting input. a controlled frequency divider, a reversible clock counter, whose code output is serially connected to the control inputs of the main frequency converter, an auxiliary frequency converter, a frequency subtraction circuit, a frequency comparison i-switch, as well as registers for input, sweep duration, cut-off frequencies operating range, with an auxiliary frequency converter connected between the counting input of the specified reversing counter and the output of the controlled frequency divider Which bits are connected to the outputs of the sweep duration registers, the control inputs of the specified auxiliary frequency converter are connected bitwise to the output of the frequency subtraction circuit, to the inputs of which, as well as the switch, the frequency frequency registers from. in order to expand its functionality, intermediate frequency and sweep time registers, intermediate frequency comparison circuits, frequency coincidence counter, switching circuit were entered into it, with the first inputs of the frequency comparison circuit being bitwise connected to the outputs of the reversible counter , and the second inputs of the frequency comparison circuit are connected to the outputs of the frequency registers and the inputs of the frequency subtraction circuit, the outputs of the frequency comparison circuits are connected to the input of the counter for the number of frequency matches, you the strokes of which are connected to the inputs of the sweep duration registers and the inputs of the switching circuit, the outputs of which are connected to the inputs of the frequency setting registers, and the reset buses are connected to the frequency comparison circuit via a frequency counter and switching circuit. Sources of information taken into account in the examination 1. The author's certificate of the USSR 239655, cl. G 01 V 1/04, 1969. 2. USSR author's certificate number 651282, cl. G 01 V 1/04, 1969 (prototype).