DE1283889B - Circuit arrangement for comparing two DC voltages - Google Patents

Description

The invention relates to a circuit arrangement for comparing two DC voltages without taking their absolute value into account.

In measurement technology as well as in control and regulation technology occurs often the problem of comparing two tensions with each other and with complete conformity of the voltage values a criterion, e.g. B. a signal voltage, too that can be used for further control tasks if necessary can.

Known solutions to this problem are based on one of the resistors formed compensation circuit, in which a switched into the compensation circuit If the voltages to be compared are equal, the measuring device shows the value Shows zero (zero adjustment). Such circuits based on a voltage or current measurement are based, work with a low slope, d. i.e., minor deviations from the zero balance do not result in a pronounced counter-criterion.

Other known solutions make use of electronic circuits which respond at a certain voltage value (threshold value). This includes the voltage discriminator known as the Schmitt trigger. With this electronic switch it can be determined whether a voltage A to be measured is smaller than a comparison voltage B; however, it cannot be distinguished whether the voltage A is exactly the same as the voltage B or whether A is greater than B.

There is also an electronic switch with three stable positions known, the one positive and one negative control current and the control current Are assigned to zero. - Only one of the named control currents. A comparison of two voltage values is possible with this switch not possible.

Finally, two amplifier elements are generally known to be coupled via one of their controllable electrodes, thereby creating a bistable System to create.

The invention is based on the object of a circuit arrangement to develop that avoids the disadvantages of the known arrangements and a voltage comparison made possible regardless of the absolute value of the voltages.

According to the invention, a circuit arrangement for comparing two DC voltages without taking their absolute value into account consists of a multivibrator provided with two amplifier elements; with one input each for connecting the voltages to be compared and one output each for tapping as criteria for the existence of voltage equality (Ui = U2) or positive or negative deviations (Ui> U2 or Ui <U2) ; Serving output signal voltages which have the same polarities when the voltages are equal (quasi-stable state of the circuit) and with positive deviations a different polarity (first stable state) than in the case of negative deviations (second stable state).

Further refinements of the invention and their mode of operation are provided explained on the basis of the exemplary embodiments shown in the drawing. In the Drawing means F i g. 1 an embodiment of the circuit arrangement according to the invention, F i g. 2 shows a supplementary circuit for obtaining a single output signal Equality of input voltages, F i g. 3 shows a circuit arrangement for one of the Circuit according to FIG. 1 pre-stage to be connected in the case of high-resistance voltage sources and F i g. 4 is a diagram showing the relationship between the input voltage - Ui and the output signal voltages Uai and Ua "at constant voltage - U2 shows.

In Fig. 1, 1 and 2 each denote a transistor of the npn type. The input DC voltages to be compared are shown as batteries 3, 4 with an adjustable voltage value or adjustable EMF. The operating voltage UB for the circuit arrangement is between terminals 5, 6 on the one hand and ground on the other. The terminal 5 is connected via a resistor 7 to the collector connection 8 of the transistor 1, the emitter connection 9 of which is connected to the negative pole of the battery 3 via a diode 10 . In an analogous manner, the terminal 6 is connected via a resistor 11 to the collector connection 12 of the transistor 2, the emitter connection 13 of which is connected to the negative pole of the battery 4 via a diode 14. The positive poles of the batteries 3, 4 are grounded. The diodes 10, 14 are connected in the forward direction with respect to the polarity of the batteries.

From the terminal of the resistor 7 facing away from the terminal 5, a current path leads via a resistor 15 to the base terminal 16 of the transistor 2 and at the same time to a resistor 17 which is connected to the negative pole of the battery 3 and to the cathode of the diode 10. In the same way, a current path leads from the terminal of the resistor 11 facing away from the terminal 6 via a resistor 18 to the base terminal 19 of the transistor 1 and at the same time to a resistor 20 which is connected to the negative pole of the battery 4 and the cathode of the diode 14 .

A first output signal Ual and a second output signal Ua2 are at one output terminal 21 and 22 or at the collector connections 8 and 9 of the Transistors 1 and 2 tapped.

The mode of operation of the circuit described above is as follows: The circuit arrangement and in particular the value of the resistors 15 and 18 is dimensioned so that with the same voltage values of the input voltages U1 and U2, a quasi-stable state occurs, which is possible in addition to two stable switching states in which either the Transistor 1 or transistor 2 is completely blocked. With the same input voltages U1 and U2, both transistors are blocked to about 90%. This state corresponds to the intersection point S between the curves Uai and Ua2 of the diagram in FIG. 4; Uai and Ua2 are then positive.

Is, however, z. BUi smaller than U2, ie U1 more negative than U2, so the base voltage for transistor 2 is also more negative. This corresponds to a control of the transistor 2 in the blocking range. As a result, the potential at the collector connection 12 becomes more positive and the transistor 1 becomes more conductive because of the coupling between the collector connection 12 and the base connection 19 of the transistor 1. At the same time, the more negative input voltage U1 also has an effect via the diode 10 on the emitter voltage of the transistor 1 , which thereby also becomes more negative and makes the transistor 1 more conductive. This results in a reduction in the collector potential or the output voltage Ual, as a result of which the transistor 2 is switched to the blocking state via the resistor 15. This state corresponds to the first stable position of the circuit arrangement. The output voltage Ua is in this state. positive, the output voltage Ual negative (see point N in FIG. 4) and Ual approximately equal to U1.

The second stable state of the circuit arrangement then results if the input voltage U1 is greater than U2, d. H. if U1 is more positive than U2 (see point P in FIG. 4). Then, in an analogous manner, the transistor 1 enters the Blocked state and the transistor 2 in the conductive state, whereby the output voltage Ual positive, the output voltage Ua2 negative and Ua2 approximately equal to U2.

The polarity of the output voltages Ual and Ua2 can thus be used independently of the absolute value of the input voltages U1 and U2 as a criterion for ensuring that U1 is either less than, greater than or equal to U2; namely the following applies: If the output voltage 1. Ual is positive, then Ui is greater, ie more positive than U2; 2. Ua2 positive, then U1 is smaller, ie more negative than U2.

If the output voltages 3. Ual and Ua2 are positive, then U1 is equal to U2.

Since in many cases an output signal is only desired when U1 is equal to U2, ie when Ual and Ua2 are positive, the output terminals 21 and 22 can be connected to the inputs 23 and 24 of a logic circuit as shown in FIG . 2 is shown.

The arrangement known as a conjunction circuit (“and” circuit) consists essentially of two diodes 25, 26, the anodes of which are connected to one another and are connected to an operating voltage UB 1 via a resistor 27. The cathode of the diode 25 is connected to the output terminal 21 and the cathode of the diode 26 is connected to the output terminal 22. If positive potentials appear at the terminals 21, 22 at the same time, the diodes are reverse-biased. A potential U "corresponding to the voltage difference between Ual and Ua2 on the one hand and UB 1 on the other hand occurs at an output terminal 29 which is at the same potential as circuit point 28. If, on the other hand, one or both output terminals 21 and 22 do not receive a positive potential, then one of the smallest occurs Input voltage Ual, Ua. Corresponding potential U ", which can practically be zero or negative, so that a potential above zero appears at terminal 29 only when two positive potentials are present at terminals 21 and 22 at the same time.

Within the area indicated by hatching 30 in F i g. 4, no clear statement is obtained as to whether - U1 is greater or less than - U., because on both sides of the abscissa value - U2 is the output signal voltage Ual and Ua. are still positive. However, this range can be so small if necessary make sure that the accuracy of the display is not affected. The circuit arrangement according to FIG. 1 requires low-resistance input voltage sources Ui and U2. Should high-resistance voltage sources are compared with each other, then it is useful to a preliminary stage according to FIG. 3 to be switched on. The preliminary stage fits the high internal resistance of the input voltage sources Uel and Ue. to the inputs 31, 32 of the circuit in F i g. 1 at.

The circuit of the preamp is completely symmetrical. It contains two transistors 33, 34 of the PNP type, the collector connections of which are connected directly to one another and to a terminal 35 to be connected to the negative operating voltage UB 2 , their emitter connections to ground via a resistor 36, 37 and their base connections to a resistor 38, 39 are connected to the input voltage sources Uel and Ue2 to be compared and, on the other hand, via a resistor 40, 41 each to taps 42, 43 of a voltage divider from the series resistors 44, 45 and 46 . The ends of the resistors 44 and 46 facing away from the resistor 45 are connected to ground, and the resistor 45 is an adjustable resistor whose wiper is connected to the terminal 35. With the wiper of the setting resistor 45, the preliminary stage can be balanced. The low-resistance outputs of the preliminary stage, which are designated by 47 and 48, are connected to terminals 31 and 32 of the circuit according to FIG. 1 connected. For a practical embodiment of the circuit arrangement according to the invention, the following resistance values are given: 7 and 11 ................... 10 kOhm 15 and 18 ........ ........... 100 kOhm 17 and 20 ................... 12 kOhm 27 ............ ............. 18 kOhm 36 and 37 ................... 1 kOhm 38, 39, 40 and 41 .... ........ 47 kOhm 44 and 46 ................... 22 kOhm 45 ............... .......... 160 kOhm The voltages to be compared are expediently in the order of magnitude of the operating voltage UB 1.

The advantage of the arrangement according to the invention is essentially based on the low circuit complexity, the large display steepness, the feedback effect and the independence of the display from the absolute value of the value to be compared Tensions.

Claims (1)

Claims: 1. Circuit arrangement for comparing two DC voltages without taking their absolute value into account, characterized by a flip-flop circuit provided with two amplifier elements (1, 2) each with one input (31, 32) for connecting the voltages to be compared (U1, UZ) and one each Output (21, 22) for tapping output signal voltages (Ual, Ua2) which serve as a criterion for the existence of voltage equality (U1 = UZ) or positive or negative deviations (U1 or <U2), which have the same polarities (quasi-stable state of the circuit) when the voltages are equal ) and in the case of positive deviations have a different polarity (first stable state) than in the case of negative deviations (second stable state). 2. Circuit arrangement according spoke 1, characterized in that the first input (31) via a resistor (17) to the base terminal (16) of a second transistor (2) and via a diode (10) to the emitter terminal (9) of a first The transistor (1), the second input (32) via a resistor (20) to the base connection (19) of the first transistor (1) and via a diode (14) to the emitter connection (13) of the transistor (2), the collector connection (8) of the first transistor (1) via a resistor (15) to the base connection (16) of the second transistor (2) and the collector connection (12) of the second transistor (2) via a resistor (18) to the base connection (19 ) of the first transistor (1) is connected and that the output voltages (Ual and Ua2) can be tapped directly at the collector connections (8, 12) . 3. Circuit arrangement according to claim 2, characterized in that the transistors (1, 2) are of the npn type, the negative pole of the voltages to be compared (U1 and U2) is at the input terminals (31, 32), the cathodes of the diodes (10, 14) face the input terminals (31, 32) and the collector connections (8, 12) of the transistors (1, 2) are each connected to the positive pole of the operating voltage (U & 1) via a resistor (7, 11). 4. Circuit arrangement according to claim 3, characterized in that a logic circuit consisting of two diodes (25, 26) is provided to form a display signal voltage (UQ) only when the input voltages (U1, U2) are the same, the cathodes of which are connected to the output terminals (21, 22) can be connected and the anodes of which are directly connected to one another, are jointly connected to the operating voltage (UB l) via a resistor (27) and have an output terminal (29). 5. Circuit arrangement according to Claim 1 or the following, characterized in that when comparing high-resistance voltage sources (Uei, Ue2) in front of the inputs (31, 32) of the circuit arrangement, a preliminary stage (F i g. 3) is switched on for the resistance voltage. 6. Circuit arrangement according to claim 5, characterized in that the preliminary stage contains two transistors (33, 34) of the pnp type, the collector terminals of which are directly connected to one another and to the negative pole of a negative operating voltage source (UB2), the emitter terminals of which are each connected via a resistor (36, 37) with ground and their base connections on the one hand via a resistor (38, 39) each to the input voltage sources (Uel, Uez) to be compared and on the other hand via a resistor (40, 41) with taps (42, 43) of a voltage divider from the resistors (44, 45, 46) are connected, and that the ends of the resistors (44, 46) not connected to the resistors (40, 41) are connected to ground and the resistor (45) of the voltage divider is designed as a setting resistor, whose slider is connected to the negative operating voltage (UB 2).