DE1092058B - Device for generating electrical impulses - Google Patents

Description

GERMAN

The present invention relates to an apparatus for generating electrical pulses using of blocking oscillators with transformer magnetic cores, which have saturation properties.

In electronic computing devices there is a need for devices for generating electrical energy Pulses, which for a given amplitude and pulse duration with a predetermined time interval follow one another. A special case of such general Devices called program generators are pulse generators for feeding shift registers, in which shift pulses in a predetermined time sequence alternately a number of Sliding windings or groups of sliding windings are fed.

A known shift register with storage magnetic cores of a rectangular hysteresis loop has a Input for signal pulses that are fed to a first winding of the first storage magnet core, one output winding each, which is also in the input circuit of a transistor amplifier and with a third winding is fed back, which is in the output circuit of the transistor amplifier and with the first winding of the subsequent storage core is connected, and a fourth winding each, which the Shift pulses are fed to all nuclei at the same time. The feedback transistor amplifier serves only to transmit the signal pulses from one magnetic core to the other, without changing the pulse times themselves.

The object of the present invention is to provide a simple pulse generator which is constructed according to the blocking oscillator principle and saturable magnetic cores and transistors as essential Contains components.

A further development of the invention consists in creating a pulse generator which, in a simple Way allows a change in the pulse duration.

The invention relates to a device for generating electrical pulses in which Transistors each with a primary winding and a secondary winding of at least one transformer are connected with a saturable core to a corresponding number of blocking resonant circuits, and consists in that the magnetization state of the transformer core or the transformer cores by bias and / or choice of the number of turns of one attached to at least one of the cores Winding is also influenced by the duration, amplitude and / or time interval of the generated pulses to vary.

In this device, the above-mentioned pulse devices are used for generating
electrical impulses

IBM Germany

International office machines

Gesellschaft mb H.,
Sindelfingen (Württ), Tübinger Allee 49

Dipl.-Ing. Karsten E. Drangeid,

Thalwil, Zurich (Switzerland),
has been named as the inventor

values largely independent of the applied load as well as any scatter that may occur and fluctuations in the parameters of the transistors used.

With this circuit, logic circuits can be set up in a simple manner, even with multiple Series connection deliver perfect results.

Compared to known devices there is the great advantage of the device according to the invention, that apart from the pulse shaping and change of the above-mentioned pulse characteristics a very extensive one Decoupling between the input circuit and output circuit is achieved, so that interference pulses the Do not endanger operational safety.

Exemplary embodiments of the subject matter of the invention are described below with reference to the drawings explained in more detail.

Fig. 1 shows the hysteresis loop of a magnetic material, as it is for the magnetic cores in the present case Pulse generator is used;

Fig. 2 is a diagram showing the dependence of the magnetic flux in a core with ideal Illustrates saturation characteristics of magnetizing current strength;

3 a is a basic diagram to illustrate the mode of operation of an embodiment the pulse generator according to the present invention;

3 b illustrates another exemplary embodiment of the pulse generator according to the invention ;

Fig. 4 is the circuit diagram of a pulse generator for generating a series of three consecutive ones Impulses;

009 630/278

Fig. 5 is the circuit diagram of a pulse generator according to the invention for generating pulses with variable duration;

6 is a schematic diagram for explaining the time-limiting effect in a variant of the Pulse generator according to the present invention.

The hysteresis loop shown in FIG. 1 serves to illustrate the fact, which is significant for the present invention, that the change in the magnetic flux caused by a given change in current is dependent on the previous state of the magnetic material. For example, the same increase in magnetization current (and thus of H) corresponds to a smaller change in induction B when the core is in a state corresponding to point 11 than when it was in a state corresponding to point 12. Points 11 and 12 correspond to states of positive and negative bias, while remanence points 10 and 14 correspond to zero bias. When a premagnetization is applied, the transition of the core to a state of positive or negative saturation will result in a change in flux, which is a function of the initial state. For a given pulse amplitude, the duration of a pulse generated in a coil attached to such a core is directly proportional to the change in flux; this makes it possible to change the pulse duration through premagnetization.

Fig. 2 illustrates the magnetization Θ of a magnetic core as a function of the magnetization current /, assuming that the magnetic core has an ideal, essentially rectangular hysteresis loop. Since the pulse duration is always proportional to the change in magnetic flux of the core with a constant pulse amplitude, the duration, as long as the work is carried out in the area represented by the steep branch of the curve to the left of the inflection point 16, depends heavily on the applied magnetizing current. If, on the other hand, the change in the magnetic flux θ is small as a function of a change in the magnetization current strength, as illustrated by the branch running flat to the right of the inflection point 16, the pulse has an essentially constant duration. If it has been achieved by applying a premagnetization that the magnetization current supplied by an input pulse exceeds the threshold value illustrated by point 16 ', the duration of the induced output pulse will remain essentially unchanged even if the first-mentioned pulse is increased considerably.

3 a and 3 b are schematic circuit diagrams of pulse generators according to the present invention.

Meanwhile, in the circuit according to FIG. 3a, the pulse generator is put into operation when over a pulse is transmitted to any one of the cores 21 'or 21 "via one OR the other, the start-up of the pulse generator according to FIG. 3b takes place if and only if both cores 21 'and 21 "(one AND the other at the same time) transmit pulses of suitable polarity The triggering of a pulse by the pulse generator is therefore linked to the fulfillment of a condition: Fig. 3a is an "OR" circuit, in Fig. 3b by an "AND" circuit.

A magnetic core 17, which is illustrated in Fig. 3a as a rod core and hysteresis properties is provided with two windings 22 and 23. The winding 22 connects the collector of the Transistor 19 with a voltage source which is connected to terminal 24. The winding 23 connects the base electrode of transistor 19 via a series circuit of windings 18 'and 18 " on the cores 21 'or 21 "with the terminal 26 of a preload battery. The preload is selected so that that the transistor is normally blocked. The polarity of the windings 18 'and 18 "is one

ίο such that switching one of the cores 21 ', 21 " or both in the windings 18 'or 18 "generates a pulse of such polarity that the transistor 19 becomes conductive. The current flowing through the winding 22 induces a voltage in it which is very the value of the battery voltage at terminal 24 will soon be reached. The back induced in the winding 23 Current has such a polarity that the current conduction of the transistor 19 is increased. The current through the Winding 22 and the transistor 19 grows up to

ao a saturation value, which is determined by the number of turns ratio of windings 22 and 23 and the properties of the transistor is determined. If this Saturation value is reached, the self-excitation effect of the circuit ceases and the pulse dies away.

It should be noted that the number of turns of the windings 18 'and 18 "are selected so that the The base current of the transistor 19 flowing through these windings does not change the state of magnetization in a lasting manner of the cores 21 'and 21 ", i.e. that the cores are not caused by the base current are switched over, their windings 18 'and 18 "essentially representing a short circuit. The circuit according to Fig. 3b also contains two cores 21 'and 21 ", although the attached, the base circuit of the transistor 19 associated windings 18 'and 18 "over their respective associated Decoupling resistor 27 'or 27 "are parallel between the terminal 26 and the winding 23.

In contrast to the circuit according to FIG. 3a, there is only one simultaneous change in the state of magnetization of both cores 21 'and 21 "with the result that the normally blocked transistor 19 is conductive will. The process of generating a single pulse as a function of the cores 21 'and 21 ″ in combination with the information transmitted as switching pulses corresponds to the information given with reference to FIG. 3a described mode of action. In both circuits, a blocking pulse is triggered if saturable Magnetic cores are caused to change their magnetization state. Given Polarity of the pulses causing this switchover, e.g. the incremental pulse at terminal 28 (Fig. 3 b) this depends in a manner known per se on the previous magnetization state of the cores 21 'and 21 ", which are the output elements of any circuit to achieve logic operations could be.

In the circuit according to FIG. 4 there are three basic circuits, as they are in the examples according to FIGS. 3a and 3b are included, combined into a pulse generator, which not only single pulses, but a A series of three consecutive pulses can be generated. A core 30 with one attached thereon Input winding 31 is used to start up the pulse generator in a similar way to how this is accomplished by the cores 21 'and 21 "in the circuits according to FIGS. 3a and 3b. The windings 32' and 33 ', 32 "and 33", 32' "and 33 '" are each wound around two of the cores 30/37', 37737 "and 37" / 37 '"

kelt. The winding is in series with the winding 32 ' 35 on the core 30, one pole of which is connected to the terminal 34 of a bias voltage source (not shown) is connected. The winding sense of the windings 33 'and 35 on the core 30 is opposite, and the collector current of transistor 39 'therefore does not cause any retroactive change in the Magnetization state of the core 30. Because of the effect of the compensation winding 35 can Current through winding 31 also does not have any current in winding 32 ', which is connected to the collector of the transistor 39 'is connected. However, a current pulse in the winding 31 generates a current in the Winding 33 '. This current makes the transistor 39 'conductive and starts the function of the first blocking oscillator. Because of the effect of the compensation winding 35, the collector current of the magnetizes Transistor 39 'only the core 37'. The collector of the transistor 39 ″ maintains its voltage because it with the collector via a winding 32 "which is wound together on the two cores 37 'and 37" of transistor 39 'and the voltage change of the latter by one in the winding 32 "(same number of turns as winding 32 ', but opposite winding sense on core 37') generated counter-voltage is compensated. The polarity of the voltage, which is in the with the base electrode of the transistor 39 "connected winding 33" is generated, is such that the descending Edge of this voltage pulse the second blocking oscillator (winding 32 "and transistor 39") in operation puts. In an analogous manner, the third blocking resonance circuit is controlled by the falling edge of the im second circle generated pulse and delivers to the winding 38 on the core 37 '"one Output pulse. The terminals 40, 40 'and 40 "are used when connected to appropriate power sources, the Feeding of bias currents to the duration of those generated by the blocking oscillator circuits To influence impulses individually. The amplitude of the individual impulses can be changed by that the emitter electrodes of the transistors 39 ', 39 "and 39'" are connected to different voltages (terminals 41 ', 41 "or 41'"). The bias of the individual base electrodes is then appropriate adapt (terminals 36 ', 36 "or 36'"). The number of blocking oscillator circuits that can be switched one behind the other is only limited by the losses in the coils.

Another embodiment of the pulse generator according to the invention for generating pulses different length is illustrated in FIG. 5 (with the restriction to two transistors 49 'and 49 "). The number of turns of winding 42 "is greater than the number of turns of winding 42 ', whereby the pulse at the collector of transistor 49 "becomes longer than that generated at transistor 49 '. Um to prevent an additional change in flux from occurring in core 47 'when transistor 49 "is energized is, an additional compensation winding 45 is attached to the core 47 ', which between the collector of transistor 49 'and winding 42 "is on. The winding 45 must be opposite of winding 42 "have the opposite direction of winding, and the number of turns of winding 42" is less the number of turns of the winding 45 is equal to the number of turns of the winding 42 '.

The circuit according to FIG. 6 serves to illustrate the automatic shutdown on the load side of a generated pulse. Although in the variant according to FIG. 6 details of the circuit are omitted are, it is immediately understandable that the circuit shown in the previous embodiments input switching elements described and connected with similar circles to one Cascade connection can be combined. The base electrode of transistor 55 is across the winding 53 is connected to the terminal 58, to which a bias battery is connected. The collector of transistor 55 is connected to a current source connected at 54 via winding 52. Parallel to Transformer winding 52 is the winding 51 on the core 56, which is used by the Circuit generated pulse to terminate after a time interval, which is determined by the voltage integral is determined that occurs across the transformer winding 52. When the core 56 has switched, that is Transformer short-circuited, the positive feedback of the base circuit is interrupted and the Transistor 55 blocked. The energy stored in the transformer places the core 56 in its initial state return.

Claims (6)

PATENT CLAIMS: 1. A device for generating electrical pulses, in which transistors, each with a primary winding and a secondary winding, at least one transformer with a saturable core are connected to a corresponding number of blocking oscillator circuits, characterized in that the magnetization state of the transformer core (17) or the transformer cores through Premagnetization and / or choice of the number of turns of a winding attached to at least one of the cores (17) is additionally influenced in order to vary the duration, amplitude and / or time interval of the generated pulses. 2. Device according to claim 1, characterized in that the additional influencing of the magnetization state of the transformer core (s) takes place by biasing by means of a direct current source. 3. Device according to claim 1, characterized in that the influencing of the duration of the generated pulses by appropriate choice of the number of turns on at least one of the Cores (45) attached winding (42 ") is achieved. 4. Apparatus according to claim 1, characterized in that for the purpose of fixing the duration of the generated pulses of a secondary winding (52) of the transformer one on one bistable magnetic core (57) attached winding (51) is connected in parallel, such that after Switching over of the magnetic core (57), the winding (51) attached to it causes a short circuit represents for the transformer and thereby the feedback effect of the blocking oscillator interrupts. 5. Device according to claims 1 to 4, characterized in that a primary winding (23) with a known bistable magnetic cores (21 ', 21 ") containing circuit for Achieving logical operations is connected, so that the pulse generator as a function of the The result of the logic operations causes at least one pulse to be generated will. 6. Device for generating electrical pulses according to claims 1 to 5, characterized in that that a number of transistors (39 ', 39 ", 39'") each with two of their electrodes (e.g. Base electrode and collector) each with a winding (33 ', 32', 33 ", 32", 33 '", 32'"), which on each two magnetic cores (30 and 37 'or 37' and 37 "or 37" and 37 '") is attached together, connected are, and the windings mentioned, viewed from one core, in pairs opposite to one another Own winding sense, so that everyone Transistor, except the first one (39 '), by means of the falling edge of the transistor circuit that precedes it (39 ', 39 ") generated pulse put into operation, even generates one that the blocking oscillation of the next transistor circuit triggers or, in the case of the last, as a pulse to one Output winding (38) is transmitted. Considered publications:
German interpretation document No. 1 042 014. 1 sheet of drawings 009 630/278 10.60