SU784420A1 - Sound probe signal simulator - Google Patents

Abstract

THE SIMULATOR OF THE ACOUSTIC PROBE SIGNALS, containing a quartz oscillator, a synchronization node connected to the first input of the integral trigger, and through the channel trigger - to the inputs of two counting pulse generators, the outputs of which through the OR circuit are connected to the lock pulse generator and the decoder counter, the outputs of the latter through the switches and circuit AND are connected to the second input of the interval time trigger, the output of which is connected to the second inputs by a blocking pulse generator and a decoder counter, In order to ensure the possibility of checking the dynamic measurement error, it is provided with a block of random time intervals, including the frequency divider, trigger and AND circuit, the quartz oscillator connected to the first input of the AND circuit and the frequency divider, which through one of the trigger inputs connected to the second i input of the AND circuit, and the other input of the trigger is connected to the output of the syncro node (I nizatsiya, with the output of the AND circuit connected to the inputs of two generators of counting pulses.

Description

00 4 4 U. The invention relates to the field of geophysical well surveys can be used when checking the metrological characteristics of acoustic logging equipment. A device for testing the performance of acoustic logging is known. Also known is a simulator of acoustic probe signals, containing a synchronization node, channel trigger, trigger time interval crystal oscillator, counting pulse generators of the first and second channels, respectively, logic elements AND or OR, blocking pulse generator, first and second switching devices, counter-decoder, generator of radio pulses, the key controlling the operation mode of the generator of radio pulses. The device allows you to simultaneously change three parameters: T, is the time of arrival of the signal of the first channel, Tj is the time of arrival of the second channel, and T is the gap of these times. This is due to the presence in the circuit of different frequency generators of counting pulses of the first and second channels, a blocking pulse generator, a counter-decoder, as well as a number of logic elements and links to melodious nodes and elements of the device. High temporal characteristics of the device are provided by synchronization of the generators of the counting pulses of the first and second channels, as well as the blocking pulse generator from the crystal oscillator. However, the device does not provide fluctuation of the times T, Tj, T from cycle to cycle. This mode is necessary when checking the dynamic characteristics of tracking systems for the period of an acoustic signal. Taki. Ground-based wave acoustic logging equipment is often supplied with automatic systems. The aim of the invention is to provide the possibility of checking the dynamic measurement error. The goal is achieved by the fact that the simulator is equipped with a block of random time intervals including a frequency divider, a trigger and an AND circuit, the crystal oscillator is connected to the first input 01 of the AND circuit and a frequency divider whose output is connected to the second input of the AND circuit, and another trigger input is connected to the output of the synchronization node, and the output of the AND circuit is connected to the inputs of two counting pulse generators. The drawing shows a block diagram of the proposed device. The scheme contains synchronization node 1, synchronizing operation of the entire device and generation of pulses, which determine the beginning of interval times T and T, trigger 2 channels, allowing the device to produce either time T or time T, trigger three intervals, generating interval time pulses first and second channels (T, and T), crystal oscillator 4, generators 5 and 6 of the counting pulses of the first and second channels, respectively, the logical element OR 7, the generator 8 blocking pulses, containing for nor the range of generated interval times, the first switching device 9, the counter-decoder 10, the second switching device 11, logic gates And 12 and 13, a block of 14 random time intervals, frequency divider 15, trigger 16, then the operation of the device is no different from the operation of the known device. The synchronization node 1, together with the 2 channel trigger, provides device synchronization and channel separation, i.e. provides separate interval times Tj. The synchronization pulse triggers the 3 interval times to a single state, and thereby forms the leading edge of the interval times Tj and Tj. The trigger 2 channel permits the operation of generator 5 or generator 6, differing in frequency by a constant value. The interval time T or Tg is calculated. After the logic element 7 OR the counting pulses from the generator 5 or 6 are fed to the generator 8 of the blocking pulses and to the counter-deflector 10. The switching device BOM 9 selects the required blocking time, after which the first potential is supplied to the first input of the logic element 12 AND. From this point in time, after a certain number of pulses arriving at the counter-decoder 10, determined by the position of the switching device 11, the resolving potential will also arrive at the second input of circuit 12 And. At the output of circuit 12, an impulse is formed, returning trigger 3 to the initial state. Thus, the exact times T and T. are formed. Consider the operation of the device in conjunction with a block of random time intervals 14. In the device, it is assumed that the synchronization circuit generates synchronization pulses and the voltage of the industrial network having a frequency of 50 Hz. It is in this way that the frequencies of the emitters of most downhole tools are synchronized. The synchronization pulse, as before, overturns the trigger 2 channels and the trigger 3 interval times, and also the trigger 16. At the same time the 0 key is closed .. The pulses from the quartz oscillator 4 are fed to the divider 15 uninterruptedly. The synchronization circuit and the crystal oscillator 4 are not connected with each other; therefore, precisely after the arrival of the synchronization pulse, the pulse from the frequency divider. 15 turns off at a random point in time, the maximum duration of which is determined by the frequency of the quartz oscillator 4 and the division factor of divider 15. By its pulse, trigger 16 is reset, the key is opened and the net interval T is calculated: OR Tg. . Thus, the pulse duration from the output of the trigger 3 interval times appears as the sum of the net interval T, or Tg calculated by a known device, and also the interval 1 specified by block 14, Frequency Divider 15 can be controlled. Thereby, the variance of the random time interval can be controlled. The simulator can improve the accuracy of testing the performance of acoustic equipment.

Claims (1)

ACOUSTIC PROBE SIGNAL SIMULATOR containing a quartz oscillator, a synchronization unit connected to the first input of the integral burden trigger, and through the channel trigger, to the inputs of two counting pulse generators, the outputs of which are connected via the OR circuit to the blocking pulse generator and the decoder-decoder, and the outputs of the latter switches and circuit And the trigger of which the generators are counter connected to the second input of the interval times, the output is connected to the second inputs by a blocking pulse generator by a decoder, different I mean that, in order to ensure the possibility of checking the dynamic measurement error, it is equipped with a block of random time intervals, including a frequency divider, trigger and circuit I, and the crystal oscillator is connected to the first input of circuit I and a frequency divider, the output of which is through one of the trigger inputs connected to the second input of the And circuit, and the other input of the trigger connected to the output of the synchronization node, while the output of the And circuit is connected to the inputs of two counting pulse generators.