DE1257841B - Circuit arrangement for checking the logical non-equivalence of signals - Google Patents

Description

Circuit arrangement for checking the logical non-equivalence of signals In logical circuits, the problem often arises that two signals have to be checked for their inequality (non-equivalence). Circuits for carrying out such a check are already known and are also called exclusive-or circuits. They satisfy the equation of the Boolean algebra Y = ä - b -I- a - b. In order to carry out the logical operation according to this equation, the negated signals must also be present in addition to the signals themselves. If these are not originally available, then inverting elements are provided in front of or in the logic circuit, which is built up from two first logic gates with two inputs each and a third connecting gate connected downstream of these gates (cf. 1961, p. 177, fig. 175). The cost of non-linear elements and resistors is relatively large here.

An exclusive-or circuit with two inputs is also known, Via the direct voltages representing binary values to be compared to a diode bridge are placed, with two complementary in series controlled via this bridge Transistors generate the output signal. This circuit is required for reliable Work the careful maintenance of the same voltage values for the two logical ones Tensions. It should also be noted that it is also known to have logical links to be linked Apply voltages to a switch, in particular a controlled rectifier.

The invention proposes a circuit arrangement for checking the logical non-equivalence (exclusive-OR circuit), which, also from a bridge circuit Making use, with comparatively little expenditure on circuit elements and without special mutual voltage level requirements for the input signals delivers the desired result.

According to the invention this is achieved in that the bridge circuit contains two bridge branches connected to an alternating voltage (4), each of which from the series connection of a switching element and a resistor, that the input signals are fed to the control inputs of the switching elements, and that the output signal is picked up on the secondary side of a transformer, its primary side in the between the respective connection points of the switching element and resistor lying zero branch is switched on.

According to the invention, the alternating voltage can either by a pure alternating voltage or alternating voltage superimposed on a direct voltage are formed. The latter option is particularly important when in a with direct current working logical network a check of signals their antivalence is necessary with relatively simple means.

In the sense of the invention it is also possible that the changing Voltage is formed by a switching edge of a DC voltage change that generated by one of the switching elements when it is triggered by an input signal will. In such an operating case, with the circuit arrangement according to the invention Impulses are monitored for their simultaneous appearance. Meet the impulses at different times at the input terminals of the circuit arrangement according to the invention on, it emits an output signal.

According to a further embodiment of the invention it is provided that to store the output signal on the secondary side of the transformer a rectifying one Element and this downstream a storage element are provided. As a storage element can expediently connect a capacitor and a resistor in parallel be used.

A particularly preferred further embodiment of the invention provides before that to check the non-equivalence of three signals the primary winding in two winding parts with different winding directions is divided, with two of the Signals are applied to one end of each of the two primary winding parts and the third Signal is applied to the other two ends of these primary winding parts. Such Arrangement is particularly advantageous when a large number of signals are simultaneous must be checked for their non-equivalence. In the following, the Invention will be explained in more detail with reference to the drawing.

F i g. 1 shows a first embodiment of the invention, with which the antivalence of two signals can be checked; F i g. 2 shows a second Embodiment of the invention for checking the antivalence of three signals.

In the exemplary embodiments in FIGS. 1 and 2 show circuit arrangements which can be used in logic networks operating with direct current and in which it is assumed that an alternating voltage is available. Rectifiers 1 and 2 controlled according to FIG. 1 are used as switching elements. In the sense of the invention, however, it would of course also be possible to use transistors, relays or contacts and the like as switching elements. A DC voltage source 3 is used as the operating voltage for the controlled rectifiers 1 and 2; an alternating voltage from the source 4 is also superimposed on this. The signals a and b are sent to the control electrode of the controlled rectifiers 1 and 2, the signal a and b respectively switching the controlled rectifier 1 and 2 conductive. The load resistors 5 and 6 are located in the cathode circuit of the controlled rectifiers. The direct current signals are picked up from these via corresponding filter means (not shown) and sent to further downstream logic circuits 7 and 8. The alternating voltage is used as an auxiliary voltage to monitor the non-equivalence of the input direct current signals a and b. It is also taken from the load resistors 5 and 6 and applied symmetrically to a transformer 9. A protective resistor 10 is also arranged in series with the primary winding of the transformer 9. However, the latter has no significance for the essence of the invention. A rectifier 11 is connected to the secondary winding of the transformer 9 and rectifies the alternating voltage to be transmitted and delivers it to a downstream storage element, which consists of a capacitor 12 and a resistor 13. At the output 14, a direct current signal can be picked up, which represents a criterion for whether or not there is antivalence between the direct current signals a and b.

If no signals a and b are present at the control inputs of the controlled rectifiers 1 and 2, the rectifiers 1 and 2 remain blocked and there is no voltage on the primary winding of the transformer 9; As a result, no signal is generated at the secondary winding of the transformer, but if signals a and b are present at the control inputs of the controlled rectifiers 1 and 2, then both rectifiers are switched on and the load resistors 5 and (have the same voltage As a result, there is no voltage difference in the primary winding of the transformer 9, so no current flows and no current is induced in the secondary winding either.

In the two operating cases explained so far, the signals were a and b are each equivalent to one another, and at output 14 a criterion for this emerged no signal.

If there is a signal a on the control electrode of the controlled rectifier 1 but no signal b on the control electrode of the controlled rectifier 2, the rectifier 1 is switched through while the rectifier 2 remains blocked. As a result, there is a positive potential at the working resistor 5, whereas the ground potential remains at the working resistor 6. A voltage difference occurs at the primary winding of the transformer 9, which generates a current flow. An alternating current is induced on the secondary side of the transformer and rectified in the diode 11. The resulting direct current charges the capacitor 12. A DC voltage signal can now be picked up at the output 14 as a criterion for the fact that the two signals a and b are different from one another and thus the non-equivalence condition is met.

If several signals are to be checked for their non-equivalence, then a corresponding number of circuit arrangements according to FIG. 1 on a disjunction linked together. Is at least one of the signals to be checked different of the other signals, a signal appears at the output of the disjunction. Are on the other hand, if all signals to be monitored are equal to each other, then the disjunction occurs no output signal.

In Fig. 2 shows a circuit arrangement with which three signals can be checked for their antivalence in a particularly simple manner. The difference to the arrangement according to FIG. 1 consists essentially in the fact that the primary winding of the transformer is divided into two winding parts with opposite winding directions. With 21, 22 and 23 controlled rectifiers are referred to, at the control electrodes of which the signals a, b and c are present. A DC voltage source 24 is used as the supply voltage, and an AC voltage source 25 is used as the auxiliary voltage. The resistors 26, 27 and 28 are arranged as the respective working resistance in the cathode circuits of the controlled rectifiers. The direct current signals are picked up at these load resistors via corresponding filter means (not shown) and are sent to downstream logic circuits 29, 30 and 31. The alternating voltages are also taken from the mentioned load resistors and applied to the two winding parts 32 'and 32 "of the primary winding of the transformer 32. The two winding parts are connected in such a way that the input of the winding part 32 connects to the cathode circuit of the controlled rectifier via a protective resistor 33 21 is in connection, while the output of this winding is connected both to the cathode circuit of the controlled rectifier 22 and to the input of the winding 32 ″. The output of this winding is connected to the cathode circuit of the controlled rectifier 23 via a protective resistor 34.

A diode 35 for rectifying the alternating currents induced in this winding and a storage element consisting of a capacitor 36 and a resistor 37 are connected to the secondary winding of the transformer 32. Signals can be picked up from this storage element at output 38 if the direct current signals a, b, c are different from one another, while if these signals are identical (equivalence) at output 38, no signal is produced.

The circuit arrangement according to FIG. 2 is constructed so that when there are input signals a and b at the control electrodes of the controlled rectifiers 21 and 22 and there is no signal c at the control electrode of the controlled rectifier 23 at the winding part 32 'of the primary winding of the transformer 32 due to the same potential at both Terminals no current flows, while a current flows in the winding part 32 ″ , which induces a current in the secondary winding of the transformer, which leads to the charging of the capacitor 36 via the diode 35.

If only signal a is present, but signals b and c are not present, a voltage difference arises at the two terminals of winding part 32 "of the primary winding of the transformer, which causes a current to flow in this winding part; winding part 32 ', on the other hand, remains de-energized, Because ground potential is present at both of its terminals.

If only signal b is present, it flows through the two winding parts 32 'and 32 "of the transformer a current. Due to the opposite winding sense However, these windings add the two currents and induce in the secondary winding of the transformer 32 a current.

If signals a and c are present, but signal b is not, then flows from the load resistors 26 and 28 via the winding parts 32 'and 32 " in each case a current across the working resistor 27 to ground potential. Because of of the different winding directions of the winding parts 32 'and 32 "add up two currents in the primary winding of the transformer 32 and induce in its Secondary winding a current, which in turn charges the capacitor via the diode 35.

These explanations show that in all those cases in which the signals a, b, c are different from one another, a signal can be picked up at the output 38 as a criterion for the antivalence of these signals.

This described arrangement is particularly advantageous Use if a large number of signals are checked for their antivalence should, since only one according to the invention is used to check three signals Circuit arrangement must be used.

Claims (2)

Claims: 1. Circuit arrangement for checking the logical non-equivalence of signals (exclusive-OR circuit) with a bridge circuit whose equilibrium is disturbed in the event that the signals do not match, so that a current flows in its zero branch, characterized in that the bridge circuit contains two bridge branches connected to an alternating voltage (4), each of which consists of a series connection of a switching element (1, 2) and a resistor (5, 6), so that the input signals are fed to the control inputs (a, b) of the switching elements and that the output signal is picked up on the secondary side of a transformer (9), the primary side of which is switched on in the zero branch located between the respective connection points of the switching element and the resistor. 2. Circuit arrangement according to claim 1, characterized in that the alternating voltage is formed by a pure alternating voltage or an alternating voltage superimposed on a direct voltage. 3. Circuit arrangement according to claim 1, characterized in that the alternating voltage is formed by a DC voltage change generated by one of the switching elements itself when it is controlled by an input signal. 4. Circuit arrangement according to claim 2 or 3, characterized in that a rectifying element (11) and a storage element (12, 13) downstream of this are provided for storing the output signal on the secondary side of the transformer. 5. Circuit arrangement according to claim 4, characterized in that the parallel connection of a capacitor (12) and a resistor (13) is used as the storage element. 6. Circuit arrangement according to one or more of the preceding claims, characterized in that for checking the antivalence of three signals, the primary winding of the transformer (32) is divided into two winding parts (32 ', 32 ") with different winding directions, two of the signals each at one end of the two primary winding parts and the third signal at the other two ends of these primary winding parts. Considered publications: IBM Technical Disclosure Bulletin, Vol. 8, No. 1, June 1965, p. 190; No. 2, July 1965, p. 330.