SU1000970A1 - Geophone system - Google Patents

Description

(54) SEISM ACCEPTABLE SYSTEM

The invention relates to multi-channel wired channel separation systems and can be used to register weak signals from various spatially distributed sensors, for example, in seismic techniques, telemetry, etc. A multichannel seismic receiver is known for a communication system comprising seismic receivers, signal transducers, an asymmetrical multichannel wire system, terminal receivers of signals and two-terminal corrective signals, a shunt input of each one of them. The disadvantage of this system is the lack of noise immunity due to the impossibility of reducing the mutual effects between channels in the signal frequency band. A well-known seismic receiver system with wired channel separation, containing an asymmetrical multichannel cable wiring, and in each channel there are seismic receivers, a signal converter, which triggers symmetrical quadrupoles in the form of a paraphase decisive amplifier, and terminal receivers of signals. At the same time, in order to attenuate the mutual influence of the channel between the channels along a common bus in a wide frequency range, the outputs of the four-pole network are connected to the reference inputs of the seismic receiver and the converter, and the inputs are connected to the common bus. However, when spatially spread or 11 areal arrangements of seismic receivers (or their groups), in the conductors of communication, seismic receivers with signal transducer input and corresponding output of the quadrupole, reaching tens to hundreds of meters in such cases, induced by various industrial facilities (electrical networks, facilities communications, industrial electromagnetic emitters, etc.) EMF interference. These EMFs impact in total between the reference input of the converter, having a fixed common bus width, and its signal input. With the increase in the interfacial distance, seismic receivers or their separate MI groups, and consequently, the interference from the conductors increases and many times exceed the level of mutual influence on the common bus. Purpose of the Invention ™ Improving noise immunity in electronic impact effects. For this pair of elements of the direct and reverse transmission of a paraphase critical amplifier, the parts are divided between which the seis receiver is connected and consistently. kidney, and the second output of the amplifier is connected to the signal input of the converter. In addition, each paraphase amplifier is made in the form of a serial connection of an operational amplifier with a remote input of a single-pass inverting amplifier containing serial VC / POC transistors with a mutually complementary conductivity type and covered by a 1-IB reducer divided by a negative reverse voltage zi Ma (, 1 is a schematic diagram of a seismic receiver system; FIG. 2 is a diagram (}) of a common amplifier1. The system contains V) -channel 1; an asymmetrical wired system, including a common common zero bus 1 and.;, 1-nalya. wires 2 are from 1 to Y), and in each channel there is a two-port circuit (or a group of them) 3, three channels): an converter 4 signals (for example, a filter, an encoder, etc.), which unites an electronic quadrupole 5 and terminal receivers of signals 6 (for example, a transformer, a seismic amplifier, nak (knowledge, etc.). Converter 4 has signal. 7 3-1 reference 8 inputs (differential input) and its output 9 Cher wire5shki 2 is connected to the inputs 10 terminal receivers 6, the reference inputs 11 of which through a common thing 1 and a quadrupole 5 connected with the reference input 8 of the converter 4, are closed in the signal transfer circuit from the output of the latter 9. Each quadrupole 5 is designed as a paraphase solver amplifier containing a low-noise amplifier 12 with outputs 13 and 14 and differential (15) 16 , covered by a negative feedback circuit through a pair of elements (for example, resistors) of forward and reverse gear circuits divided into parts 17, 18 and 19, 20. All resistors 20 are connected to the common zero. bus 1, seismic receiver 3 through resistors 21 and extended driver 22 are connected to common points of elements 19 and 2O, and common points of elements T7 and 18 are connected to each other via a serial / RO-chain 23. The second output 24 of a quadrupole 5 is connected directly to the signal input 7 of the converter 4. Electrical power supply to all electronic devices of the system of FIG. 1 is supplied with respect to a common zero & bus 1. The amplifier circuit 12 (FIG. 2) contains an operational amplifier 25, connected in series with a single-input inverter amplifier 26, encircled by negative feedback resistors 27 and 28. Amplifier 26 contains an input branch made on transistors 29 and 30, resistors 31 33, as well as an amplifying branch on the series connection of transistors 34 and 35 with a mutually complementary conductivity type of resistor 36, and a voltage follower (transistors 37 and 38). The system (FIG. 1} works as follows. Pry equal values of pairs of elements 17 21 in each quadrupole 5, which can be achieved, for example, by means of thin-rimmed kcroelectronicity, the effect of common-mode, -surface disturbances induced in long conductors 22, decreases in accordance with the attenuator ratio and the common-mode mecha (at least 7O – 8O dB), which is typical of a 25 / differential input amplifier with a diff / penny input. Similarly to the e (I) signal, the quadrupole 5 has a suppression effect signals on a common bus 1. At the same time, due to the differential activation of the seismic receiver 3 relative to the entrances of the quadrupole 5, the seismic signal is amplified by R RiQ4-Rj UR2; i / Rao) times, starting from the lower limit frequency $ - (R, C;). Further rejection of residual common mode signals on

Outputs j 3 and 14 of amplifier 12 are made possible by connecting them between signal 7 and reference 8 inputs of converter 4. Equivalent voltage of the reduced displacement zero amplification l 12 and its drift are infrared-frequency signals for which the RC-chain has almost infinite impedance transmitted to output 13 and 14 with a transfer factor of .j .1

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guaranteeing unsaturated operation and undistorted seismic signal processing in devices 4 and 5. This improves the signal-to-noise ratio and increases the noise immunity of the system with spatially extended or areal seismic receivers.

In the case of spatial placement together with a seismic receiver, three four. of the 5 emf disturbance interference is induced on the communication wires of its outputs with the converter 4 inputs and is applied to the signal already amplified in the four-pole 5 without deterioration of the signal-to-noise ratio. However, in this case,

EMF is induced by interference that is effectively suppressed only when the inputs of the 1.2 V1 amplifier are connected to it as a common-mode signal. This is achieved by the circuit design of the amplifier 26 as follows.

The input branch, made on transistors 29 and 30, resistors 31 - 33, performs (function of matching the level and nuts of the exhaust signal of amplifier 25c with the level and phase necessary to ensure the operation of the amplifier pair performed on transistors 29 and 30. and resistor 31 The output signal of the amplifier 25, which is shifted to the required levels by the input branch, is removed from the resistor 31 inverted in phase to the input of the field-effect transistor 34 connected in a common-gate circuit, at the same time it is removed without changing the phase from the divider including transistor 3 0 and resistors 32 and 33, to base transistor 35, whereby transistors 34 and 35 are one for another

dynamic load and provide a high gain ratio of the circuit, necessary for precise inversion of the output signal of the amplifier 25 at

its coverage by a divider 27 and 28 reverse C z z. Performing the amplifying branch on transistors 34 and 35 with a mutually additional type of conductivity allows connecting their control transitions to the power sources + En and -En, due to which the EMF interference in the power supply is practically equally affects these transitions and is effectively suppressed. The high degree is suppressed by the above mentioned interference by the operational amplifier 25, provided by the differential: | -resolution {its construction of the input kokadad, practically does not deteriorate when the amplifier 12 is switched on due to the noise immunity of the additional amplifier 26 and the absence of the HBA331 input circuit with a total thickness 1.

Thus, the proposed system combines high noise immunity with the weakening of the high-frequency effects when using unbalanced wired systems.

Claims (2)

1. A seismic receiver with a channel-channel separation system containing an asymmetrical multichannel system of wires and in each channel seismic receivers, signal converters that unite the four-pole in symmetrical four-pole circuits in the amplifier of a paraphase swarm; the converter, and the inputs are connected to a common asymmetrical wired system, and the terminal receivers of the signal are mains, so that, in order to improve the noise immunity under the conditions of electromagnetic effects, the pairs The elements of the forward and reverse transmission of the phase decisive wuxi, the cores are divided into parts, between which seismic signals and the sequential & CS chain are respectively connected, and the second amplifier is connected to the signal input of the converter. 2, The system in accordance with claim 1; This is due to the fact that each paraphase amplifier is made in the form of a serial connection of an operational amplifier with a differential input and a single-ended inverting amplifier containing a series connection of transistors with a mutually additional conductivity type and covered by a resistive negative feedback divider. Sources of information, for application number 2081117, cl. G01V 1/28, taken into account in examination 5 1974 (prototype). 1000970 1. USSR author's certificate No. 276173, class, H 04 B C / PA, 1968. 2. USSR author's certificate