CS252565B1 - Absolute value amplifier connection - Google Patents

Abstract

The amplifier consists of a feedback network absolute value amplifiers, composed of operational amplifiers, addition amplifiers, two diodes and their respective resistors. To increase the response speed of the circuit are between the opamp and the first and second diodes two current converters are inserted so that they are excited from the power amplifier power terminals. The op amp output is Resistive to which the first compensation may be added a member that is either grounded or connected to an inverting one operational amplifier input. On the input of the amplifier can be connected to resistor, which is connected to the feedback resistance by the other end network connected to the amplifier input, The common point of these resistors can then be connect the second compensation circuit to alignment speed of both transmission branches. Engagement solves problems of speed, sensitivity and stability amplifiers of absolute value and measurement rectifiers with operational amplifiers.

Description

(54) Absolute Amplifier Connection

The amplifier consists of an absolute value feedback network consisting of an operational amplifier, an addition amplifier, two diodes connected to each other and the respective resistors. To increase the response speed of the circuit, two current reversers are interposed between the operational amplifier and the first and second diodes such that they are excited from the operational terminals of the operational amplifier. The output of the operational amplifier is loaded with a resistor to which the first compensating element can be connected, which is either earthed or connected to the inverting input of the operational amplifier. A resistor can be connected to the input of the summing amplifier, which is connected to the feedback network resistor connected to the amplifier input at the other end. A second compensation circuit can then be connected to the common point of these resistors to equalize the speeds of both transmission branches. The circuit solves the problems of speed, sensitivity and stability of absolute value amplifiers and measuring rectifiers with operational amplifiers.

AND

The invention relates to an absolute value amplifier solving problems of speed, sensitivity and stability of these amplifiers and measuring rectifiers with operational amplifiers.

Operational rectifiers or absolute value amplifiers with operational amplifiers are increasingly used to measure AC voltages and currents. Commonly used circuits are only suitable for measurements at technical frequencies. At frequencies above 1 kHz, their accuracy and sensitivity decrease due to the considerable inertia of the operational amplifiers.

It is known that the speeds and sensitivity of these circuits can be increased by connecting an auxiliary fast amplifier between the output of the opamp and the diode limiter. This, however, complicates the stability conditions of the feedback network considerably, so that the circuits formed usually oscillate parasitically. The parasitic oscillations can only be eliminated by substantially reducing the upper cut-off frequency of the operational amplifier, so that the acceleration effect obtained is only relatively small. Only such operational amplifiers with outlets for connection of external compensation circuits can be used for such wiring.

Auxiliary fast amplifiers are usually complex, and must include a number of components for both temperature and frequency compensation, so setting up auxiliary circuits is not only costly, but also laborious and time consuming.

Absolute value amplifiers are known where current reversers are used as auxiliary fast amplifiers connected to the operational terminals of the operational amplifier.

All known absolute value amplifiers have two unequally fast signal transmission paths, which has a major effect on the output signal distortion when the input signal polarity changes. As a result, especially at higher frequencies, the output waveform does not match the absolute value of the input waveform.

The above disadvantages are overcome in the circuit according to the invention. The amplifier consists of an operational amplifier and an addition amplifier. On the inverting input of the operational amplifier, one end of the first resistor is connected, the other end of which is the input of the entire amplifier and is connected via a sixth resistor to the summing amplifier input. A cathode or a resistor is also connected to this summing amplifier input via a fifth resistor. anode of the first diode whose anode resp. the cathode is connected to the cathode respectively. and the second diode.

Anode resp. the cathode of the second diode is connected via a third resistor to an inverting input of an operational amplifier, at the output of which a load resistor is connected. Between the anode resp. the first current reverser is connected between the cathode, the first diode and the first power amplifier power terminal. a second current reverser is connected to the second diode anode and the second operational amplifier power terminal.

It is an object of the invention that a first compensating member is connected between the output of the operational amplifier and the ground or its inverting input to accelerate the response of the operational amplifier and / or an inverting input of the operational amplifier is connected. and a seventh resistor is connected between the sixth resistor and the summation amplifier input and a second compensating member is connected to its common point with the sixth resistor, the other end of which is grounded.

The advantage of this circuit is that the load of the opamp can be selected to substantially improve the phase response of the feedback loop by including the first compensating element while maintaining the maximum possible response rate. In order to provide the highest response rates, this circuit allows to bridge the operational amplifier with a transistor (eg FET) voltage monitor. This ensures stable operation of the amplifier even when the limit frequency is over 1 MHz. The output waveform can be substantially improved by including the second compensating member in a faster transfer branch.

The accompanying drawings show examples of connection of an absolute value amplifier according to the invention. Fig. 1 shows schematically the connection of the whole amplifier with both compensating members and Fig. 2 shows an alternative of the frequency compensation connection with the follower.

The diagram in Fig. 1 has a conventional absolute amplifier feedback chamber. This feedback network is formed by an operational amplifier to whose inverting input one end of the first resistor is connected, which is connected to the amplifier input by the other end. Furthermore, one end of the second resistor is connected to the inverting input of the operational amplifier 2, the other end of which is connected in this case to the cathode of the first diode.

The cathode of the first diode is connected via the fifth resistor to the input of the summing circuit 2 'which is also connected via the sixth resistor to the input of the amplifier and thus to the other end of the first resistor R1. An inverting input is connected to one end of the third resistor R R, the other end of which is connected in this case to the anode of the second diode The anode of the first diode and the cathode of the second diode D ₂ are connected and

In an amplifier according to the invention, however, between the anode of the first diode and a first power supply terminal 11 of the operational amplifier 2 connected to the first current reverser reverser 2 · second stream 2 is then connected between the second power terminal 12 of the operational amplifier 2 ^and the cathode of the second diode D _2nd An operational resistor 2 is connected to the output of the operational amplifier 2, which is grounded, to which a first compensating member 5, which can be either earthed, or connected to an inverting input of the operational amplifier 2, is connected in parallel. is the seventh resistor R connected? and to the common point of the sixth resistance R ^ and the seventh resistance R _? a second compensating member 6 is connected, which is grounded.

In the simplest case, the first and second compensating members 5, 2 are formed by capacitors.

The first diode and the second diode D ₂ may also be oriented in the opposite direction; but they are always involved against each other.

The amplifier works as follows:

If a negative voltage is applied to its input, this voltage is maximally amplified by the opamp 2 ^and Ρθ of the passage of the first current reverser 2 ^{and the} second current reverser 2 3 ^{e at} their outputs reversed its polarity. At the anode of the first diode it is therefore a positive voltage, so that this first diode opens and transmits a signal first, via a second resistor back to the inverting input of the operational amplifier 1, ^{and 0} amplitude corresponding to the ratio of the second resistor IL, and the first resistor and via the fifth resistor to the input addition amplifier 2.

The signal at the input of the addition amplifier 2 is added to the signal that is transmitted directly through the sixth resistor R R and the seventh resistor R _?. . There is also a positive voltage at the cathode of the second diode D ₂ , so that the second diode D ₂ remains closed.

If positive voltage is applied to the amplifier input, this voltage is again maximally amplified by the operational amplifier 2 ⁱⁿ conjunction with the first and second current reversers 2 /

2, which at the same time reverses its polarity and outputs negative voltage. As a result, the first diode remains closed and the second diode D ₂ opens.

The third resistor R ^ mediates a negative coupling which maintains near zero voltage at the inverting input of the operational amplifier 2. In this case, the signal from the absolute amplifier input to the summation amplifier input 2 is only transmitted through the sixth and seventh resistors Ηθ, R ?.

In order to increase the feedback loop stability and to increase the response speed of the operational amplifier 2, a first compensating member 2r is connected ^to its output which is either grounded or, as indicated by dashed lines, connected to the inverting input of the operational amplifier. In the simplest case, the first compensating member is formed by a capacitor.

Although the response of the first compensating member 5 increases the response speed, this response at the input of the summing amplifier 2 is delayed compared to the signal arriving at the input of the summing amplifier 2 through the sixth and seventh resistors Rg, R ?.

To avoid this time shift between the two signals, is the common node of the sixth resistor Rg and the seventh resistor R _? a second compensating member 6 is connected, in the simplest case again a capacitor. This second compensating member 6 actually delays the signal coming from the absolute amplifier input through the sixth resistor Rg.

The function of the first compensating member 2 can be replaced by the emitter follower 11, FIG. 2. This circuit has the fastest response. The input of the emitter follower T is connected to the inverting input of the operational amplifier 2 and the output is connected both via the first capacitor to the first power terminal 11 of the operational amplifier 1 and through the second capacitor C1 to the second power terminal 12 of the operational amplifier 2.

As a result of the inclusion of this emitter follower T, the operational amplifier 2 is bypassed at very high frequencies and thus prevents its oscillation due to excessive phase shift of the operational amplifier 2 itself.

The first and second capacitors, C _2, serve for the direct separation of the output of the emitter follower T from the first and second current reversers 3, 1.

Depending on the use of the absolute value amplifier, the first compensation element and / or the second compensation element 2 and / or the compensation alternative with the emitter follower 2 The absolute value amplifiers according to the invention may be constructed from discrete components as hybrid or possibly monolithic integrated. Circuits from discrete components will be faster, hybrid integrated will be the most economical in production.

Claims (1)

SUBJECT OF THE INVENTION An absolute value amplifier wiring consisting of an operational amplifier and an adder, where one end of the first resistor is connected to the inverting input of the operational amplifier, the other end of which is the entire amplifier input and connected via a sixth resistor to the adder amplifier input. cathode resp. anode of the first diode whose anode resp. the cathode is connected to the cathode respectively. the anode of the second diode, whose anode resp. the cathode is connected via a third resistor to the inverting input of the operational amplifier, to the output of which a load resistor is connected and between the anode resp. The first current reverser is connected between the cathode of the first diode and the first power amplifier power terminal. a second current converter is connected to the anode of the second diode and the second power amplifier power terminal, characterized in that a first compensating member (5) is connected between the output of the operational amplifier (1) and ground or between the output of the operational amplifier (1) and its inverting input; / or an inverting input of an operational amplifier (1) is connected to an input of an emitter follower (7), the output of which is connected both through the first capacitor (cp with the first supply terminal (11) and through the second capacitor (C ₂ ) with the second supply terminal ( 12) an operational amplifier (1) and / or between the input of the amplifier (2) and the sixth resistor (Rg) is connected to the seventh resistor (R?) And to the common point of the sixth resistor (Rg) and the seventh resistor (R ^) a compensating member (6), the other end of which is grounded.