DE1945908A1 - Measuring circuit for differential amplifier - Google Patents

Description

Measuring circuit for differential amplifiers Flow circuits for differential amplifiers with voltage or current series negative feedback is used because of their high input resistance generally for voltage measurement.

If the output variable of the amplifier is to be an impressed voltage, so one will choose a voltage series negative feedback. With a current series negative feedback on the other hand, one achieves an impressed current.

In the case of a differential amplifier that is to be used for voltage measurement, you have to pay special attention to two sources of error. Once upon a time there is one error voltage, generally referred to as the offset voltage, must be taken into account. It is determined in particular by the inequality of the base emitter voltages of the two Transistors of the first difference stage generated. By balancing resistors in the emitter or collector circuit of the transistors or by generating a compensation voltage this error voltage can be adjusted to zero at least at a constant temperature will. It is not so easy to deal with the disturbance emanating from the other source of error to prevent. It is caused by the fact that a transictor amplifier is not powerless works, but to set the drbeitpunkte of the amplifier input stage Base currents needed. These flow in a differential amplifier from the inverting and from the non-inverting input to the zero potential, which is im is generally identical to the center tap of the supply voltage source. Both currents cause a resistor in their circuit Voltage drop which leads to a corruption of the measured value.

It is known that the two input currents of a differential amplifier are about the same size, by using the sum of the resistances that between the inverting input and zero potential, equal to the sum of the Resistors makes that between the non-inverting input and zero potential lie. By-this wet measure is achieved that the caused by the input currents . Voltage drops are also the same and cancel each other out. pre-condition for this method to be successful is that the two input currents of the Differential amplifiers are really the same size. Eggs there is once the opportunity to provide so-called transistor pairs for the first transistor stage, i.e. transistors, in which the parameters, in particular the current gain factors, if possible match exactly. On the other hand, there are also circuits that provide an accurate Allow balancing of the two amplifier input currents. So if the internal resistance the Meßspamlungsquelle, the one of the two differential amplifier inputs in the circuit is known, it means no difficulty in the circuit of other input to introduce an equal resistance and thus through to mutually compensate for the error voltages caused by the input currents.

If the amplifier is used in stationary operation, it remains always with the same measurement source.

connected together, so is the internal resistance of this measurement voltage source generally known or easy to determine. However, it is different with an amplifier which is used in a transportable measuring device, e.g. a multiple.

instrument that is built in. The chip sources then used for measurement will have very different levels of internal resistance, the values of which are also in general üiibekann: t are. Would it be possible to measure the voltage of such a measuring voltage source switch off, so that only their passive internal resistance on Input of the amplifier is, so you could see the current through the input to it detect the fault voltages caused, since there is a correspondingly large of Would set zero deviating amplifier output variable. So you could see that maybe the connected internal resistance of the measuring voltage source is so low is that it does not cause any noticeable error, or otherwise see it, how big the measurement error is. If the latter were the case, there would still be the possibility the other.

Equip the amplifier input with a potentiometer and thus the Adjust error voltage to zero; Unfortunately, this procedure is very rare Cases applicable since the voltage of a measuring voltage source in general cannot be switched off in the desired form. When the measuring voltage is applied, however, it does not tell how far it or the error voltage affects the amplifier output influenced.

Regarding the state of the art, it should also be noted that it is also known that respective negative feedback principle, voltage or current series negative feedback, with differential amplifiers can be achieved in two different types of circuit. Both countercopes -Izmg: spriezipe allow the amplifier to be used as either an inverting or non-inverting amplifier to switch.

In the case of a non-inverting amplifier, there is the negative feedback voltage at the inverting input, so that a counteracting the non-inverting input Potential shift occurs. In the case of the inverting amplifier, on the other hand, the Negative feedback voltage of the measuring voltage source switched directly in opposition, so that this is largely compensated for. In general it doesn't matter which one of the two types of circuit is chosen for an amplifier, but the one is non-inverting Amplifier can only be implemented with a differential amplifier.

The object of the invention is to find a solution how to do with measuring voltage sources can determine the measurement error caused by it with an unknown internal resistance. The determination of the measurement error should be possible in spite of the applied measurement voltage and without it cumbersome additional measurements with which e.g. the internal resistance could be determined, ausko = en.

Furthermore, the invention should allow the measurement error by a to compensate adjustable resistance.

This object is achieved according to the invention in that, depending on the switching position a changeover switch the negative feedback takes place so that the negative feedback voltage either is applied to the inverting amplifier input or the measuring voltage source is connected directly opposite is, in both switching positions, however, the same amount of negative feedback occurs and the respective negative feedback principle of voltage or current series negative feedback preserved. The measurement error compensation takes place in such a way that a resistor per after switching position of the switch either in the circuit between zero potential and inverting amplifier input or between zero potential and non-inverting Amplifier input is switched. To this resistance the two measuring voltage sources to be able to adjust, it is useful to make the resistance variable, so that it consists of one or more potentiometers or of switchable individual resistors consists. Since the adjustment of the resistance inevitably takes place in such a way that its value equals the value of the internal resistance of the measuring voltage source, it is advantageous to to display the set value of the resistor digitally or analogously.

The advantages achieved with the invention are in particular: that it is possible with an unknown measuring voltage source, due to its internal resistance caused measurement errors to recognize 80 that he was in the evaluation of the oil result in Invoice can be set. While so far voltage measurements to avoid incorrect measurements could only be carried out on such measuring sources, the ion resistance of which a does not exceed a certain limit value, the internal resistance must now be substantial to be taller. Furthermore, the invention allows by connecting a resistor to adjust the measurement error to zero without having to switch off the measurement voltage. Since he balanced resistance with the same input currents inevitably equal to the If the resistance of the measuring voltage source is, a potentiometer only has to have an ohmic scale be provided in order to determine the value of the internal resistance at the same time can. The circuit therefore also offers a very convenient solution for resistance measurement ssung, especially for measuring the internal resistance of voltage sources; because this one can be done using known methods, e.g. by measuring the change in voltage when changing a load resistance, it is very difficult to determine.

An embodiment is shown in the drawings and in described in more detail below: Fig. 1 shows' the differential amplifier with changeover switch with current series negative feedback.

Fig. 2 shows the same circuit bpi voltage series negative feedback.

As far as the components in the two figures correspond in their mode of operation, The same code numbers were used for better clarity.

As FIG. 1 shows, the two inputs la, Ib lead to a differential amplifier 1 to a changeover switch 2. The amplifier output 1c is via the load resistor 3 connected to a voltage divider consisting of three resistors 4,5,6.

The resistor 6 is on one side at zero potential, which is identical is connected to the center tap of a power supply source not shown here, the one that feeds the amplifier 1 via the connections le. Both sides of the resistance6, at which the negative feedback voltage is generated, are connected to the switch 2. In the switching position 2a, the changeover switch connects the inverting amplifier input la with a measuring voltage source 7 and its internal resistance 8 and this in turn with the resistor 6. The circuit of the non-inverting amplifier input 1b is via a balancing resistor 9 and a potentiometer 10 to zero potential closed. In the switching position 2a is proportional to the output current Negative feedback voltage that is generated at the resistor 6, the measurement voltage source 7 switched in the opposite direction.

In the switch position 2b, the negative feedback voltage generated at the resistor 6 is via the potentiometer 10-fed to the inverting input la, while the non-inverting Amplifier input Ib via the balancing resistor 9 with the measuring source 7 is connected, which in turn is unilateral is at zero potential. The Neß circuit works as follows: The potentiometer 10 is short-circuited and the internal resistance 8 of the measurement savings source 7 is zero, then - provided that that both input currents of the amplifier 1 are the same - the amplifier output variable (Output current or output voltage) in both switch positions of the switch 2 must also be the same. The one in the circuit of the non-inverting input 1b From equ. Calibration resistance- 9 is dimensioned so that its value is equal to the value of the resistance between the inverting input 2a and zero potential is, so with resistance 6 <resistance 5 approximately equal to the resistance 6. In in practice the internal resistance 8 of the measuring voltage source is of course not zero. This means that in the switching position 2a the amplifier input current from the inverting Amplifier input la and in the switch position 2b the amplifier input current from non-inverting amplifier input a voltage drop across the internal resistance 8 produce. Both voltage drops have the same but opposite change the output variable. The difference between the output variables, once in the switch position 2a and then measured in switch position 2b is inevitably twice as large, like the actual measurement error, so it must be added depending on the switching position or subtraction to the measured output variable can be taken into account.

If the amplifier input current is known, the measurement error the internal resistance of the measuring voltage source can also be calculated. However, about unnecessary To save arithmetic; the potentiometer 1-0 was added to the circuit.

With the help of the switch 2 it is alternately in the circuit of the inverting and the non-inverting amplifier input are switched, and always so that the internal resistance 8 of the measuring voltage source 7 in each case in the other Circuit lies. As soon as the potentiometer 10 starts from zero in its resistance value is increased, the measurement error is decreased. The adjustment of the potentiometer is controlled; by switching between the two switching positions 2a, 2b several times will. If the output variable is the same in both switching positions, the adjustment is made ended and the resistance of the potentiometer 10 equal to the internal resistance 8 of the Measurement voltage source 7.

liat the potentiometer 10 is provided with a resistance scale, so, after the adjustment has taken place, the value of the internal resistance of the measuring voltage source can be read directly.

The operation of the circuit shown in Fig. 2 corresponds the circuit of Fig. 1. here it is only a voltage series negative feedback, i.e. the load resistance 3 is now no longer in series with the voltage divider 4,5,6, but parallel to dienem and another connected in series \ 'iderstald 11. The arrangement of the voltage divider was 4,5,6 chosen arbitrarily, so it can look completely different. The same is true of course also for the construction of the switch 2 and the associated network.

Claims (5)

Claims 1. 1. Measuring circuit for differential amplifiers with voltage or current series negative feedback, characterized in that, depending on the switching position of a changeover switch (2), the negative coupling takes place in such a way that the negative feedback voltage is either at the inverting amplifier input (la) is applied or the flow voltage source (7) is connected directly opposite ', in Both switching positions (2a, 2b), however, an equally large negative feedback occurs and the respective negative feedback principle, voltage or current series negative feedback preserved. 2. Measuring circuit for differential amplifier according to claim 1, thereby characterized in that a resistor (10) depending on the switching position (2a, 2b) of the multi-pole Changeover switch (2) either in the circuit between zero potential and inverting Amplifier input (1a) or between zero potential and non-inverting amplifier input (1b) is switched. 3. Measuring circuit according to claim 1 and 2, characterized in that the resistor (10) is variable and consists of one or more potentiometers or switchable single resistors. 4. Measuring circuit according to claim 1 to 3, characterized in that a corresponding device-the set value of the resistor (10) digitally or similarly. 5. Measuring circuit according to claim 1, characterized in that before the non-inverting amplifier input (1b) is connected to a compensation resistor (9) which is equal to the resistance that is present when the measuring voltage source is short-circuited (7,8) lies between the inverting input (1a) and zero potential. '