CS211550B1 - Wiring for remote control amplification of closed loop amplifier - Google Patents

Abstract

The invention relates to a circuit for remote control of the closed loop gain of an amplifier. The gain is changed by changing the value of the feedback resistor. The resistance of the lead wires does not affect the value of the feedback control resistor.

Description

The invention relates to a circuit for remote control of the amplifier closed loop gain. The change in gain is done by changing the value of the feedback resistance. The resistance of the supply wires has no influence on the value of the feedback control resistance.

Previously known amplifier control circuits include supply resistors to the feedback control resistor. The disadvantage of these wiring is the impossibility of setting the zero output voltage and the dependence of the gain on the resistance of the supply conductors. Another known circuit utilizes selsyn control, which is complicated by the necessity of using auxiliary sources.

The above-mentioned drawbacks are alleviated by a circuit for remote control of closed loop amplifier with parallel voltage coupling consisting of an operational amplifier of feedback resistors and supply resistors, according to the invention, characterized in that the first supply resistor is connected via a feedback resistor to the input voltage terminal , on the one hand through the second supply resistor to the inverting input of the operational amplifier, on the other hand to the first end of the feedback control resistor, the other end of which is connected to the third supply resistor connected to the output terminal of the operational amplifier; operational amplifiers.

By incorporating the feedback control resistor according to the invention, the change in the loop gain is independent of the lead resistance. If the feedback control resistance is zero, the input variable is zero. The actual control resistor can be located a long distance from the operational amplifier without the need for auxiliary circuits or power supply. These advantages apply to feedback elements with both a real resistance component and an imaginary component and to different types of feedback.

21,550

An exemplary embodiment of the invention is illustrated schematically in the accompanying drawing, in which the functional connection of an operational amplifier with feedback elements, replacement resistors of the input wires with input and output circuits is shown.

The input voltage or current terminal 1 is connected to the feedback resistor R1. the other end of which is connected to a first supply resistor RVI. The second end of the first supply resistor RV1 is connected to the summing point 2 of the operational amplifier OZ1. the feedback control resistor R2 and the first end of the second feeder EV2.

The other end of the second supply resistor RV2 is connected to the inverting input 8 of the operational amplifier OZ1. The third supply resistor RV3 is connected with the other end to the output terminal 6 of the operational amplifier 0Z1 and the first end to point 2 to which the second end 6 of the feedback control resistor R2 and the first end of the fourth supply resistor RV4 are connected. which is connected at its other end to the output 8 of the amplifier. The common terminal 2 of the operational amplifier 0Z1 is connected to a common conductor 40, the voltage of which is considered to be the voltage at the input voltage terminal 1 and at the output 8 of the amplifier.

The operation of the closed-loop gain amplifier with remote control is as follows: the voltage from the input voltage terminal 1 is applied to the feedback resistor R1 and the first supply resistor RVI. The feedback control resistor R2 is connected to the operational amplifier 0Z1 and to other circuits by conductors with first to fourth supply resistors RVI. RV2.

RV3 RV £. The closed-loop voltage gain of the closed-loop operational amplifier 0Z1 with parallel voltage coupling, defined as the ratio of the output U VST and the input voltage U VST with feedback resistor R1 and feedback control resistor R2, is much greater than J_ with the formula _CELECT _ R2 ^AU 'UVST ^- R1 + RVI

Where Au is the closed loop voltage gain, U VST is the voltage considered between the output 8 of the operational amplifier OZ1 and the common wire 10 and U VST is the voltage considered between the terminal i of the input voltage and the common wire 10.

It can be seen from the equation that for R1 + RVI = constant, the amplifier voltage gain is a function of the feedback resistance R2. Second and third supply resistors RV2. RV3s are included in the open loop gain of the amplifier and do not apply under the above open loop gain condition. The fourth supply resistor RV may be included in the feedback of the next stage, or may be neglected due to the input resistance of the next stage.

Claims (1)

Wiring for remote amplification of closed loop amplifier with parallel voltage feedback consisting of operational amplifier, feedback resistors and supply resistors, characterized in that the first supply resistor (RV,) is connected via a feedback resistor (R,) to terminal (, input voltage, through the second supply resistor (RV2) to the inverting input (3) of the operational amplifier (OP), and secondly, to the first end (5) of the feedback control resistor (R2), the other end (6) of which a third supply resistor (RV3) connected by the other end to the output terminal (4) of the operational amplifier (OZ), and to a fourth supply resistor (RV4), the other end of which is the output (8) of the operational amplifier (OZ1).