DE1149055B - Electronic switching device with magnetic cores - Google Patents

Description

The invention relates to electronic switching devices and circuits containing such devices.

In the following description, references are made frequently to magnetic cores. Under the The term "magnetic core" is understood to mean a ring-shaped magnetic core made of a material which has a substantially rectangular hysteresis loop. Such cores can according to the top or bottom of the hysteresis loop magnetized in one or the other of two directions will.

In the following, a core magnetized in one direction is considered to be in the "set state" and, when magnetized in the other direction, as being in the "readjustment state" designated.

Magnetic core memory in the form of a matrix of magnetic cores used in the field of electronic Calculating machines are well known, require electrical switching units that respond to an input signal respond to emit an output signal in the form of a current pulse of a certain amplitude, to switch the magnetic core memory. If possible, it is also common to use the switching units to be connected in series in order to obtain a shift register which, upon receipt of a pulse train of so-called switching pulses send a single output pulse in succession to a large number of output channels leads.

Electronic circuits that can be used with magnetic core memories are already known, which have a single magnetic core. However, if such switching units in a shift register are to be used, it is necessary to provide storage members for each unit, which store the information while the next core in the circuit from the one previously stored in it Information is cleared. To achieve this storage, it is known to insert a transistor into the Circuit and use the entire memory effect of the transistor to generate the output pulse to extend. The transistor must be operated in the saturation range, whereby the The speed at which the transistor can be switched is reduced.

It is also known to allow such storage by a further magnetic core in each switching unit effect, but in this known circuit there is another one that is intertwined with the first pulse train A second sequence of switching pulses is required to switch the other magnetic cores.

Electronic switching device
with magnetic cores

Applicant:

Ferranti Ltd.,
Hollinwood, Lancashire (UK)

Representative: Dr. B. Quarder, patent attorney,
Stuttgart O, Richard-Wagner-Str. 18th

_t g Claimed priority:

Great Britain January 28, 1959 (No. 3004)

Charles Hodgson, Cheadle, Cheshire

(Great Britain),
has been named as the inventor

It is an object of the present invention to provide an electronic switching unit with an output to create, which can operate a magnetic core memory and which is designed so that various Switching units can be connected in series.

According to the invention, this object is achieved by an electronic switching unit with a first magnetic core, which has an adjustment winding, a re-adjustment winding and an output winding, and with a positive feedback branch with one between the output winding and the adjustment winding of the first magnetic core lying transistor, solved in that a second magnetic core with an adjustment winding, a reset winding and an output winding is provided, the Reset winding connected to input terminals for receiving an input pulse and the output winding of which is connected in series with the output winding of the first core, and that one end of the adjustment winding of the first core is connected to an output terminal, in operation the transistor controls the flow of current in the setting winding of the first core so that the first Kern takes a longer time to switch from one position to the other than the second Core.

309 597/26?

The switching device can also include a resistor which is in parallel with the output winding of the first core is switched.

An electronic switching arrangement can also have a plurality of the switching devices described, which switching devices are sequentially arranged, with the reset windings of the second cores of the devices are connected in series with one another and with exception in the first device of the order the setting winding of the second core in each device Series connected to the setting winding of the first core of the preceding device in the sequence is.

The invention is described below, for example, with reference to the drawing, in which

Fig. 1 is a circuit diagram of a switching device,

Fig. 2 is a circuit diagram of a switchgear with the switching devices shown in Fig. 1 and

3 shows a circuit diagram of a modified embodiment of the switching device shown in FIG is.

The electronic switching device according to FIG. 1 of the drawing has a second magnetic core 1, which an adjustment winding 2, a re-adjustment winding 3 and an output winding 4, and one first magnetic core 5, which has an adjustment winding, a reset winding 7 and an output winding 8. One end of the output winding 4 of the second magnetic core 1 is connected to a terminal 9 and the other end to one end the output winding 8 of the first magnetic core 5 is connected. The other end of the output winding 8 is connected to the base of a transistor 10. The collector of transistor 10 is at one end of the Setting winding 6 connected, the other end of which is connected to an output terminal 11. The emitter of transistor 10 is connected to a terminal 12. The setting winding 2 is connected to terminals 13 and 14, the reset winding 3 to terminals 15 and 16 and the reset winding 7 to terminals 17 and 18 connected.

In the operation of the device, the cores 1 and 5 occur at the base of the transistor 10 and more Collector current flows. This cumulative effect continues until the whole stream becomes the constant stream supplying device flows through the transistor 10. After the core 1 by the input pulse has been reset, the transistor 10 remains due to the continuous change in state of the core 5 continues to be conductive. When the core 5 is saturated, i. H. is in the setting state, no further output voltage occurs at the output winding 8 and the transistor 10 therefore stops suddenly to head on.

A resistor can be used so that the period of time in which the transistor 10 conducts can be precisely determined 19 (shown in dashed lines) must be placed parallel to the output winding 8. The one on the winding 8 occurring output voltage causes a current flow through the winding 8 and the resistor 19 in the direction in which the speed of the state change of the none 5 is reduced will. The time required by the core 5 to reach saturation is therefore of the size of the Resistance 19 dependent.

The output signal of the device taken from the output terminal 11 is therefore a current pulse certain amplitude, which is particularly suitable for controlling a magnetic core memory.

After the switching process has ended, the core 5 is thereby changed to its reset state, that a suitable current is passed through the reset winding 7 via the terminals 17 and 18 will. Alternatively, a suitable bias current can flow through the entire operating time the reset winding 7 go through so that the core 5 immediately after the transistor current has stopped flowing, is reset. The device is then ready for another switching process ready.

Sometimes electronic switchgears are required that respond to a pulse train input and sequentially transmit a single pulse output to a plurality of output channels. Such systems, sometimes known as shift registers, are used to control certain

usually in their reset state and 45 types of magnetic core memories especially useful.

the transistor 10 is kept in the non-conductive state by a bias voltage applied to the terminal 9. A device is connected to the terminal 12 which is connected to the emitter of the transistor 10 supplies a constant current as soon as the transistor 10 is conductive.

In order to prepare the device for a switching operation, the setting state of the core 1 is changed by a suitable current being passed through the winding 2 via the terminals 13 and 14. Thereafter, a switching pulse is applied to the reset winding 3 via the terminals 15 and 16, which causes the core 1 to change to its reset state and thereby generates a voltage output pulse in the output winding 4. The voltage output pulse passes from the output winding 8 to the base of the transistor 10 and makes it conductive. The output current from the collector of the transistor 10 flows through the setting winding 6 to the output terminal 11 and thereby causes the core 5 to begin to change into the setting state. This causes a further output voltage at the output winding 8 and therefore In Fig. 2 there is shown a shift register system, which has a single input terminal IP and a series of twenty output channels 1 OPC, OPC 2 to OPC 20th The system has a sequence of twenty switching devices SU1, SU2 to 5 * 720, each of which is the same as the switching device described above.

The reset windings 3 of each device SU1 to SU 20 are connected in series with the input terminal IP . The base of transistor 10 in each device is biased through windings 8 and 4, and the emitter of transistor 10 of each unit is connected to a device 20 which supplies a constant current to any conductive transistor. The device 20 has a diode 21 through which the current flows when no transistor is conductive. The reset windings 7 of all devices are connected in series with one another and to a bias voltage source (not shown). With the exception of the device 5171, the adjustment winding 2 of the core 1 is in series with the re-adjustment winding 6 in each device

of the core 5 of the preceding device switched in sequence.

In operation, the two cores 1 and 5 in each device are normally in the reset state and the transistor 10 in each device is normally kept non-conductive by the bias applied to the base. In order to prepare the circuit for a subsequent switching process, the core of the unit SU1 is changed to the setting state by passing a suitable current through the winding 2. The core 1 of the device SU1 is therefore the only core in the system which is in the setting state. Thereafter, the foremost pulse of a series of pulses, hereinafter referred to as shift pulses, is applied to the reset winding 3 of each device. This foremost shift pulse has no effect on the core in any of the devices SU 2 to SU 20, since they are all in the reset state.

The core 1 in the device SU1 is, however, changed by the foremost shift pulse from the setting to the readjusting state. An output voltage pulse is generated at the output winding 4. Thereafter, the mode of operation of the device SU1 is the same as that of the device described in the previous example. In this system, however, the output signal of the device SU passes from the device SU 1 via the coil 2 on the core 1 2. Therefore, the core 1 of the device SU 2 - assuming that the transistor 10 of the device sul after the cessation of the foremost shift pulse continues to direct - changed to the setting state.

The size of the resistor 19 is chosen so that the core 5 is only saturated after the shift pulse has ceased. The core 1 of the device SU 2 is therefore changed to the setting state during the last section of the output pulse from the device SU1.

When the second shift pulse is transmitted to the input terminal IP , the only core on which it has an effect is core 1 of the device SU 2. This core is therefore reset and the device SU 2 operates in the same way as the device SU1 and supplies an output pulse to the output channel OPC 2, at the same time changes the core of the device SU 3 to the set state (ready for the third shift pulse), and in this way successive shift pulses actuate successive devices until all twenty devices have been actuated.

Immediately after the transistor 10 stops conducting in each device, the core 5 is reset to the reset state by the bias current flowing through the reset winding 7. The device is thus reset to its normal state, ready for the next actuation, and for the initiation of a further subsequent switching process it is only necessary to put the Kernl in the device 5171 in readiness so that the next series of shift pulses is transmitted to the input terminal IP can be.

In a typical application of the above system, the input signal consisted of a series of square-wave pulses with a duration of IVg microseconds each. The core 1 of every facility changes its state in a microsecond, and the core 5 of each device changed its state slightly slower, with transistor 10 in each device for approximately 3Vg microseconds directed. During the latter part of this period, Core 1 became the next unit in the sequence changed from the reset state to the set state, ready for the next shift pulse.

Fig. 3 of the drawings shows a modification of the device described above, in which the core 1 has an adjustment winding consisting of two windings 2A and 2B which are connected to terminals 13 ^ 4, 135, 14 A and 14 B. The windings 2 A and 2 B are designed so that the core 1 can be adjusted when current passes through both windings connected in series, but is not changed in its setting state when the same current passes through only one of the windings. The device can thus be used to perform a logical AND operation, as if the two windings 2 A and 2 B are not connected in series, the device may be arranged so that only the core 1 is set (and the device operated ) when two currents are passed to the two windings.

The shift register shown in Fig. 2 can be constructed with this modified form of the switching device, in which case only one of the windings 2 A or 2 B is connected in series with the setting winding of the first core of the preceding device in the sequence. The output of the preceding device is then insufficient to set the first core, unless a separate current flows in the other of the two windings. The actuation of the shift register can then be stopped at any stage without leaving a second core in any device in the set state by interrupting the current flowing in the other of the two windings.

The shift register system described is not the only system in which switching devices of the type described with reference to Figs. 1 and 3 can be used. The shift register is just as Embodiment listed.

Claims (5)

PATENT CLAIMS: 1. Electronic switching device with a first magnetic core which has an adjustment winding, a reset winding and an output winding, and with a positive feedback branch with a transistor lying between the output winding and the adjustment winding of the first magnetic core, characterized in that a second magnetic core (1) with an adjustment winding (2), a re-adjustment winding (3) and an output winding (4) is provided, the re-adjustment winding of which is connected to input terminals (15, 16) for receiving an input pulse and its output winding (4) in series with the output winding (8) of the first Core (5) is connected, and that one end of the setting winding (6) of the first core (5) is connected to an output terminal (11), the transistor in operation (10) the current flow in the adjustment winding (6) of the first core (5) controls so that the first core (5) Takes a longer time to switch from one position to the other than the second core (1). 2. Electronic switching device according to claim 1, characterized in that a resistor (9) is connected in parallel to the output winding of the first core (5). 3. Electronic switching device according to claim 1 or 2, characterized in that the setting winding (2) of the second core (1) is formed by two separate windings (2 A, 2B) . 4. Electronic switching device with a plurality of switching devices according to claim 1, 2 or 3, characterized in that the switching devices are arranged in a sequence the reset pulses of the second cores of the devices in series are connected to each other and with the exception of the first device in the sequence Adjustment winding of the second core in each device in series with the adjustment winding of the first core is switched in the preceding device in the order. 5. Electronic switchgear with a plurality of switching devices according to claim 3, characterized in that the switching devices are arranged in an order, wherein the reset windings of the second cores of the devices connected in series with one another are and with the exception of the first facility in the order one of the two windings in series forming the adjustment winding of the second core in each device connected to the setting winding of the first core in the preceding device of the order is, whereby in operation the other of the two windings to a separate power supply can be connected so that each switching device perform a logical AND function can. Considered publications:
German Auslegeschriften No. 1042014,1037509, 047 842. 1 sheet of drawings © 309 597/263 5.63