DE1043393B - Electronic gate circuit - Google Patents

Description

GERMAN

The invention relates to an electronic gate circuit with memory properties, which can be controlled by relatively short pulses.

It is known that certain substances, e.g. B. germanium silicon or indium antimony crystals, peculiar as a result of a so-called Hall effect have magnetoelectric transmission properties. If a plate of such a substance in a Magnetic field is brought and transversely and preferably approximately perpendicular to this an electric current is sent through the plate with the help of opposing electrodes, occurs between two more Electrodes apply an electrical voltage, the distance between the latter electrodes transversely and preferably approximately perpendicular to the magnetic field and to the distance between the first two mentioned Electrodes. Certain substances, e.g. B. bismuth or indium antimony, exhibit another strange one Effect, the so-called magnetoresistance or Gaussian effect. When a magnetic field crosses a Plate made of such a substance is applied and an electric current between two opposing ones Electrodes are sent across the magnetic field through the plate, so the resistance changes between these electrodes with the value of the magnetic field. The intensity of this effect increases with decreasing Temperature to, and from a certain value of the magnetic field on is the relationship between the Resistance of the plate and the magnetic field almost linear.

The invention aims to achieve the effects described for the construction of a convenient electrical gate circuit to use, whereby by the application of the mentioned magnetoelectric transmission properties in connection with a soft magnetic material with considerable remanence the gate device Has memory and possibly amplifier properties.

The gate circuit according to the invention is characterized in that it is one of at least one Control winding has a core made of a soft magnetic material with considerable remanence, furthermore means by which a remanent induction generated by means of the control winding mentioned can be eliminated, and at least one plate made of a material having magnetoelectric transmission properties and having at least one pair of electrodes is provided, which is coupled to a pair of terminals through which signals are transmitted, and on opposite side surfaces of the plate are attached, and which plate in a narrow Air gap of the mentioned core is attached in such a way that the direction of a possibly occurring Electronic gate circuit

Applicant:

NV Philips' Gloeilampenfabrieken,
Eindhoven (Netherlands)

Representative: Dr. rer. nat. P. Roßbach, patent attorney,
Hamburg 1, Mönckebergstr. 7th

Claimed priority:
Netherlands 11 April 1956

Simon Duinker, Eindhoven (Netherlands),
has been named as the inventor

Magnetic field through the core and the plate across the direction from one electrode to the other and faces the major surfaces of the plate so that the transmission of an electrical signal across the plate and dependent on the mentioned pair of clamps on the magnetic flux through the core and the plate is.

The invention is explained in more detail with reference to the drawing. It shows

1 shows a first embodiment of an electric gate device according to the invention,

Fig. 2 shows the plate, the input and the output circuit of this embodiment,

3 shows a second embodiment of the gate device,

4 shows the plate and the exciter and the output circuit of the second embodiment,

5 shows a third embodiment,

6 shows the plate, the input and the output circuit of the third embodiment,

7 shows a fourth embodiment,

8 shows the plate, the input and the output circuit of the fourth embodiment,

Fig. 9 shows a fifth embodiment, and

Fig. 10 shows the plates, input and output circuits of the fifth embodiment.

The embodiment of FIGS. 1 and 2 has a core 1, V made of a soft magnetic material with a considerable remanence, for. B. from Ferroxcube or from another soft ferrite with remanence. This core has the shape of a two-part ring, part of which has three quadrants and 1

SSB 673/145

Part 1 'of which form approximately a quadrant of the ring, with a narrow air gap remaining between parts 1 and 1'. The contact surfaces of the two parts 1 and 1 'with each other and with a thin plate 2 attached in the air gap are approximately perpendicular to each other, so that the exact position of part 1' relative to part 1 and plate 2 by displacement along the separating surface between parts 1 and 1 'can be adjusted and no additional air gap remains between these parts or between each of these parts and the plate 2. In part 1 a hole 3 is provided so that it is split over part of its length and in the direction of an approximately occurring magnetic field into two branches of the same cross section. The branches are each surrounded by an extinguishing winding 4 so that the two branches can be magnetized simultaneously and in opposite directions. As a result, an apparent additional air gap is introduced into the annular core, which virtually eliminates any residual magnetic induction of the entire core. A control winding 5 surrounds the entire cross section of another part of the core 1, 1 '. A current through this winding creates a magnetic field through the whole core and, since this core is made of a material with considerable remanence, there then remains a considerable remanent magnetic induction in the core and a corresponding field through the air gap. The plate 2 is cut from a germanium crystal and thus has a so-called Hall effect. On their sides two pairs of electrodes O ₁ 6 'and 7, T are mounted (Fig. 2). The direction from the electrode 6 to the electrode 6 'is approximately perpendicular to the direction from the electrode 7 to the electrode 7', and these two directions are approximately perpendicular to the direction of a magnetic field generated by the possible remanent magnetic induction of the core I ₁ V the plate.

The electrodes 6 and 6 'have two input terminals 9 and 9' and the electrodes 7 and 7 'with two output terminals 10 and 10 'connected. The winding 5 is supplied with control pulses from a control pulse source powered, and the winding 4 is connected to an erase pulse source.

When the winding 5 receives a control pulse, the core 1, 1 'is magnetized so that a magnetic field is generated through the plate 2 approximately perpendicular to the direction of an input current between the electrodes 6 and 6'. As a result, a voltage arises between the terminals 10 and 10 'which is approximately proportional to the input current flowing between the electrodes 6 and 6'. As long as the plate 2 is exposed to the influence of the magnetic field through the core 1, 1 ', input signals applied between the terminals 9 and 9' are thus transmitted to the terminals 10 and 10 '. Since the core 1, 1 'consists of a material with considerable remanence, a short control pulse is sufficient to ensure the transmission between the terminals 9, 9' and 10, 10 '. This core thus plays the role of a memory that remembers that it has received a control impulse. The memory of this control pulse is erased as soon as the winding 4 is supplied with an erasing pulse with the above sign or even an alternating current pulse. The maximum amplitude of the erase pulse must be large enough to saturate the two branches of the split part of the core 1, 1 'in opposite directions. Compared to the remanent magnetic induction of the entire core, this part of the core 1, 1 'behaves like a relatively wide additional air gap during the erase pulse, so that the remaining field through the core I ₁ 1' and the plate 2 is greatly reduced. Since the plate 2 is no longer traversed by a noticeable magnetic field, it loses its transmission properties based on the Hall effect, so that the signal applied to the terminals 9 and 9 'is not

ίο more is transferred to terminals 10 and 10 '.

It could possibly be sufficient that the

Winding 4 around only one of the branches of the split part of the core I ₁ 1 '. In fact, the magnetic resistance of the path over the two branches of this part is much smaller than that over the whole core, which also includes an air gap, albeit a narrow one.

3 and 4 show a second embodiment, which also has a core I ₁ 1 'from a

ao soft magnetic material with considerable remanence, a Hall plate 2 and windings 4 and 5 as it has the first embodiment. The core I ₁ Y has the same shape as that of the first example, and the plate 2 is also mounted in a narrow air gap of this core which is provided with a hole 3 through which the winding 4 is wound. As can be seen from Fig. 4, the electrodes 6 and 6 'of the Hall plate are, however, connected directly to the terminals of an excitation current source 8, and the input terminals 9 and 9' are connected to an input winding 11 which also contains the core 1, 1 ' surrounds (Fig. 3). A current through this winding causes a change in the magnetic flux through the Hal plate 2, and the output voltage at the output terminals 10 and 10 'changes in accordance with this change in flux.

This action is possible as long as the core I ₁ 1 'is not caused by the control pulses in a saturation region, and so long as it has a substantial permeability in the due to the ampere-turns of the control pulse operating point.

The third embodiment according to FIGS. 5 and 6 is a so-called »Gyratorx gate circuit, that is, a transmission in a certain direction, e.g. B. in Fig. 6 from left to right, can be brought about via the Hall plate 2 by means of a first winding 5, which receives control pulses from a first control pulse source, while the pulses of a second control pulse source are fed to a second control winding 5 'and a transmission bring about in the opposite direction. Further, the gate having an erase coil 4 which is wound through a hole 3 of a cleaved portion of the core 1 I ₁ 1 'therethrough. The core 1, 1 'consists of a half-ring-shaped part 1 in which the hole 3 is provided, and of a rod-shaped part 1', the ends of which are opposite the end faces of the half-ring 1. The Hall plate 2 is attached between an end face of the half ring 1 and a side face of the corresponding end of the rod-shaped part 1 ', this end face of the half ring 1 being ground by the thickness of the plate 2, so that practically no air gaps between the contact surfaces the parts 1 and 1 'and the Hall plate 2 remain. The Hall plate 2 is provided with two pairs of electrodes 6, 6 'and 7, T of the same surface, which are attached in such a way that the distances between the electrodes of each pair of electrodes

the other are the same and that the directions from one electrode to the other of each pair of electrodes are perpendicular to one another and to the direction of a magnetic field possibly occurring through the air gap of the core 1, 1 '. The network containing the electrodes 6, 6 'and 7, T also has two resistors 12 and 12', through which the electrodes 6 and 6 'are connected to the electrodes 7 and 7'. The Hall plate 2 is square, and the resistors 12 and 12 'are equal to each other.

In the absence of a magnetic flux through the Hall plate, the latter forms a passive element in the Network between the terminal pairs 9, 9 'and 10, 10'. Under these circumstances a transfer can occur in one direction as well as in the other direction via this network, the resistors 12 and 12 'and the resistances of the distances between the electrodes of the plate 2 a weakening of the bring about the transmitted signal. A flow of a certain direction can be controlled by means of a short control pulse are generated by the winding 5, while a flux of opposite direction by means of a control pulse of the same sign can be brought about through the winding 5 '. The resistances 12 and 12 'have such a value that the presence of magnetic flux through the Plate 2 the transmission in a certain direction, e.g. B. from left to right, improved by about 6 db and the transmission in the opposite direction is practically suppressed. This is due to the fact due to the fact that the transmission is in phase in the first direction due to the Hall effect with the transmission via the resistors 12 and 12 ', while in the second direction the transmission as a result of the Hall effect counteracts the transmission via these resistors.

The retentive magnetic induction of the core 1,1 ' can be approximately eliminated by means of an erase pulse applied to the erase coil 4. Further one could naturally only use a control winding and thereby the direction of the transmission change that this winding control pulses of opposite signs are fed.

The gate circuit described above is equivalent to a changeover switch, through which a transmission in one or the other direction can be prevented, this switch by means of a short control or Erase pulses switched to one or the other of its setting positions or to its reset position and remains in the selected position until it receives a new control or cancellation pulse receives. A new control impulse, which creates a magnetic flux in the same direction as the previous one Control pulse is generated, or a second or further erase pulse has no effect on the Gate device.

7 and 8 show a fourth embodiment which forms a so-called "or" gate circuit. By means of a first control winding 5 attached to a core 1, 1 'made of a soft magnetic material with considerable remanence and connected to a first control pulse source, a magnetic flux can be generated through the core 1, 1' so that a transmission from the Terminals 9, 9 'takes place after the output terminals 10., 10'. A second control winding 5 'is attached to the core 1, 1'. This winding is connected to a second control pulse source, so that a transmission from the terminals 9, 9 'to the terminals 10, 10' can thereby be brought about. The part 1 of the core 1, 1 'is also provided with two holes 3 and 3', through which two quenching windings 4 and 4 'are wound. The core 1, Y consists of two L-shaped parts 1 and 1 '. Part 1 'has shorter legs than part 1, so that the contact surfaces of the two parts or the contact surfaces of these parts with a plate attached between them are perpendicular to one another. In this way it is achieved that practically no air gaps remain between the contact surfaces of the two core parts 1 and 1 'with one another and with the main surfaces of the plate.

The plate could be a Hall plate with two pairs of electrodes connected in the manner shown in FIG be. In this embodiment, however, the Hall plate is replaced by a plate 13 which from one substance, e.g. B. bismuth or an indium-antimony alloy, which is an essential has so-called magnetoresistance or Gaussian effect. The plate 13 is provided with a pair of electrodes 14, 14 'and is located in an electrical bridge circuit, which is shown in FIG is. The bridge circuit of Fig. 8 contains the impedance of the plate 13 between the electrodes 14 and 14 'and further resistors 15, 16 and 17. Two diametrically opposite points of the Bridge are connected to input terminals 9 and 9 'via an excitation current source 8, while the two other diametrically opposite points of the bridge with the output terminals 10 and 10 'are connected.

In the absence of magnetic flux through plate 13, the electrical bridge is approximately im Balance, so that there is practically no transmission between the pairs of terminals 9, 9 'and 10, 10' he follows. But if a magnetic flux through the core 1, 1 'and through the plate 13 by means of a control pulse is generated, a signal applied to terminals 9, 9 'as a result of the disturbance of the state of equilibrium of the bridge to the terminals 10, 10 'are transmitted. The resistance the plate 13 between the terminals 14, 14 'increases with the magnetic flux, whereby the aforementioned Disturbance of the equilibrium state of the bridge is brought about. This increase in resistance is at greater field strength is proportional to the field strength of the magnetic flux and is also considerably larger at a lower temperature than at room temperature. It is therefore advantageous to the core 1, 1 'with the Windings 5, 5 'and 4, 4' and to attach to the plate 13 in a thermostat and on a low Temperature, e.g. B. to keep the temperature of the liquid air. That way you can be a good one Achieve transmission and save one or more amplifier stages.

The magnetoresistance or Gaussian effect is strongest when the direction of the ^ magnetic flux perpendicular to the main surfaces of the plate 13 and thus also to the direction of one of the electrodes 14 and 14 'after the other, and it is of a reversal of the direction of this magnetic flux practically independent.

The usable output power of a plate with a magnetoresistive effect is proportional to the DC power supplied by the excitation power source, which is therefore taking into account the maximum permissible power loss of the plate is selected as large as possible. The terminals 9, 9 'are therefore with a signal source of low DC resistance, ζ. B. with the secondary winding of a trans-

formator connected. In a variant of this exemplary embodiment, the acquisition current source 8 is directly connected to it connected to the electrical bridge circuit, the input terminals 9, 9 'with an input winding, like the winding 11 of the example of FIG. 3. The input power thus causes Changes in the magnetic flux through the plate 13 and corresponding changes in the resistance this record.

Control pulses of any sign supplied to one or the other of the control windings 5 and 5 ' can therefore bring about a transfer from terminals 9, 9 'to terminals 10, 10', during one or the other of the quenching windings 4 and 4 'supplied erase pulses this transmission by magnetic saturation of one of the split Can suppress parts of the core part.

In each of the exemplary embodiments described so far a second plate 2 'or 13' could be attached between the core parts 1 and 1 ', as in fig 1 and 7 shown in dashed lines. The distances between the electrodes of corresponding electrode pairs these plates would then be connected in series with one another.

9 and 10 show a fifth embodiment in which the gate circuit has a "and" - Circuit forms. This embodiment has j-wei three-legged cores 20, 20 ', 20 "and 21, 21', 21" and two Hall plates 2 and 22. The part 20 and 21 of each of these cores is L-shaped and with two holes 3 and 3 ', through which an erase winding 4 or 4' is wound. The part 20 'or 21' each core represents the middle leg of this core. It is smaller than the part 20 or 21 and also L-shaped so that one of its end faces against the inner side face of one end of the part 20 or 21 rests, while its other end surface of the inner side surface of the other branch of the part 20 or 21 faces and the Hall plate 2 or 22 between this end surface and this inner side surface is appropriate. Since the end surfaces of the parts 20 'and 21' and the inner surfaces of the parts 20 and 21 are perpendicular are to each other, it is achieved that between these parts and the main surfaces of the corresponding Hall plate no air gaps remain. The third part 20 "or 21" of each core is also L-shaped and approximately the same size as the corresponding part 20 'or 21'. The end faces of these third parts 20 "and 21" rest against the outer side surface of the corresponding parts 20 'and 21' and against the inner one Side surface of the end of the branch of the part 20 or 21, in which the holes 3 and 3 'are made are. Since the contact surfaces of the parts 20 and 20 'or 21 and 21' with the third part 20 "or 21" are perpendicular are to each other, it is achieved that between the part 20 "or 21" and the other two parts practically no air gaps remain in the corresponding core. A control winding 5 or 5 'is' on the Middle leg of the core 20, 20 ', 20 "or 21, 21', 21" attached. The holes 3 and 3 'with the windings 4 or 4 'lie on both sides of the Hall plate 2 or 22 and in a section of the part 20 or 21 of the corresponding nucleus, the one between the left or right outer limb and the middle limb this core lies.

The windings 5 and 5 'have two different ones Control pulse sources connected. The Löschwickkingen 4 of the two cores are in series with one another switched and connected to a first erase pulse source, while the erase windings 4 'likewise are connected to one another in series and connected to a second erase pulse source.

The two Hall plates 2 and 22 are connected in cascade with one another. The plate 2 is provided with two pairs of electrodes 6, 6 'and 7, T , which are connected in the manner shown in FIG. The plate 22 is also provided with two pairs of electrodes 26, 26 'and 27, 27'. The electrodes 26 and 26 'are connected to the output terminals 10 and 10' of the network

ίο the Hall plate 2 connected while the electrodes 27 and 27 'are connected to the output terminals 30 and 30' of the gate device.

A transmission of a signal applied to the input terminals 9 and 9 'to the output terminals 30 and 30 'is only possible if the two Hall plates 2 and 22 are exposed to a magnetic Are exposed to the river. If only the plate 2 is exposed to such a flow, however, the signal will transferred to terminals 10 and 10 ', but the

ao not reach output terminals 30 and 30 ', since no Hall voltage occurs on plate 2. Vice versa the signal may also not reach the terminals 30 and 30 'if only the plate 22 of the action is exposed to a magnetic flux, since the signal does not pass through the plate 2 to the terminals 10, 10 'is transmitted. In order to meet the transmission conditions, it is therefore necessary to send a control pulse to supply the control winding 5 and a control pulse to the control winding 5 '. These two Pulses can follow one another at will, and every core whose control winding receives an Inipuls retains its remanent magnetic induction so that any time elapses between the pulses can. If the two cores have remanent magnetic induction, so are two different impulses are necessary for the transmission from terminals 9, 9 'to terminals 30, 30 'to interrupt. When a first erase pulse is applied to the erase windings 4, the corresponding split part of the upper left side branch of each nucleus represents an apparent air gap, so that the magnetic flux through the left outer leg of each core is interrupted. A magnetic one But river still flows through the right outer leg of each nucleus, so that the field strength of the magnetic flux through each plate 2 or 22 is only decreased, but not practically eliminated. Since the cores are made of a soft magnetic material with • a rectangular hysteresis loop, the Reduction of the magnetic flux through each plate only a few percent, so that the transfer from terminals 9, 9 'to terminals 30, 30' is maintained. Thereupon an extinguishing pulse is issued sent through the other extinguishing windings 4 ', so the magnetic circuit across the center leg of each Core practically completely interrupted, so that the remanent magnetic induction in every core is almost eliminated and there is no longer any transmission from terminals 9, 9 'to terminals 30, 30' can.

The sequence of the control pulses applied to the control windings 5 and 5 'is not important, and a second or further control pulse applied to a winding which has already received a control pulse of the same sign after the last erase pulse has no effect. Likewise, the sequence of the extinguishing pulses fed to the extinguishing coils 4 and 4 'is not important, and such a pulse can only have an effect if, after the expiry of the last control pulse, no extinguishing

pulse was applied to these windings. A transfer between the input and output terminals bring about, it is therefore necessary to at least one control pulse to the winding 5 and to supply at least one control pulse to the winding 5 ', and to interrupt a transmission it is also necessary to send at least one erase pulse to the windings 4 and at least one To apply the erase pulse to the windings 4 '. If between the two control pulses there is an extinguishing pulse z. B. is placed on the windings 4, one of the cores, z. B. the Core 21, 21 ', 21 ", magnetized, while only half of the other core is still magnetized The second control pulse still enables transmission, but a single one applied to the windings 4 ' The erase pulse is then sufficient to interrupt this transmission. The left one remains Half of the core 21, 21 ', 21 "finally magnetized until the windings 4 are supplied with a new erase pulse will. To delete the last received control pulse, there are always two different ones Erase pulses necessary.

Proceeding from the embodiment of FIGS. 7 and 8, a gate circuit with three or more alternative transmission conditions can of course be set up in that three or more control windings and, if necessary, three or more quenching windings are attached to the core 1, V. Starting from the embodiment of FIGS. 9 and 10, a gate circuit with three or more necessary transmission conditions can also be set up. For example, a circuit with three necessary conditions would consist of three four-legged cores, three plates connected in cascade with magnetoelectric transmission properties, three control windings and three groups of three erase windings each.

The cutoff frequency at which a transfer still takes place as a result of the> Hall effect is z. B. for germanium of the order of 10 ¹⁰ per. / Sec., While the magnetic resistance change of bismuth at a frequency of about 0.3 · ^{10 10} per. / Sec. decreases by half. The gate circuits according to the invention are therefore able to transmit relatively high frequencies and, if necessary, to amplify them.

The gate circuits described have the combined properties of a memory and a Switch and also cause, with the exception of the embodiment of FIGS. 5 and 6, a certain Amplification of the transmitted signal. They are applicable in all cases where these are combined Properties can be useful, particularly in control, testing, and other automatic equipment and in calculating machines. The input signals are mostly impulses that may or may not be transmitted must be, and the control and erase pulse sources are often so-called by central sources Mother pulses time pulses formed, d. H. from sources at predetermined time intervals Also deliver pulses of a certain length, polarity and amplitude.

Claims (16)

Patent claims: 1. Electronic gate circuit which can be controlled by relatively short pulses and which Has memory properties, characterized in that it is one of at least one The core surrounding the control winding is made of a soft magnetic material with substantial remanence also has means by which a remanent generated by means of the control winding mentioned Induction can be eliminated, and at least one plate made of a material with magnetoelectric Transmission properties provided with at least one pair of electrodes with a pair of terminals, through which signals are transmitted, coupled and on opposite sides Side faces of the plate are attached, and which plate in a narrow air gap of the mentioned Core is attached in such a way that the direction of any occurring Magnetic field through the core and the plate across the direction from one electrode to the other and faces the major surfaces of the plate so that the transmission of an electrical signal via the plate and to the aforementioned pair of clamps from the magnetic flux through the core and the plate is dependent. 2. Gate device according to claim 1, characterized in that said means for elimination the remanent induction have at least one quenching effect, which is attached in this way is that a current pulse sent through this winding causes local saturation of the core caused and thereby an apparent, relatively wide additional air gap in the Introduces core. 3. Gate device according to claim 1 or 2, characterized in that an optionally to applied electrical signal to an input winding surrounding the mentioned core is to change the magnetic field through the mentioned plate accordingly, and that an electric Excitation current is sent across the direction of the magnetic field through the plate, so that the signal is good in the presence of a polarizing magnetic field and in the absence of one such a magnetic field is not transmitted to the aforementioned pair of terminals. 4. Gate device according to claim 3, characterized in that said core in the means the above-mentioned control winding set operating point has a considerable permeability. 5. Gate device according to claim 1, 2 or 3, characterized in that said plate a Hall effect in a magnetic field that may occur transversely to their main surfaces and is provided with a second pair of electrodes attached to its side surfaces, the direction from one to the other of these electrodes being transverse to the direction from the one after the other of the first-mentioned pair of electrodes. 6. Gate device according to claim 1 or 2 and 5, characterized in that an optionally The electrical signal to be transmitted is fed to the electrodes of the second pair of electrodes is so that in the presence of a magnetic field through the core and the plate well and at Absence of such a field is not transmitted after the mentioned pair of terminals. 7. Gate device according to claims 3 and 5, characterized in that said electrical Excitation current is supplied to the electrodes of the second pair of electrodes. «09 67S / 145 8. Gate device according to claims 1 or 2 and 5, characterized in that a first Electrode of the first pair of electrodes via a first resistor to a first electrode of the second pair of electrodes and the second electrode of the first pair of electrodes via a second Resistance is connected to the second electrode of the second pair of electrodes and that the second pair of electrodes is coupled to a second pair of clamps and the values of the resistors are chosen such that in the presence of a magnetic field through a certain direction the core and the plate transmit signals only from the first to the second pair of terminals takes place, and that in the presence of a magnetic field in the opposite direction, a signal transmission occurs only from the second after the first pair of terminals. 9. Gate device according to claim 8, characterized in that said plate with the Electrode pairs attached thereon with respect to two between the electrodes and perpendicular is symmetrical to the main surfaces of the plate standing planes, so that the longitudinal and transverse impedances of the quadrupole formed thereby are in pairs equal to each other and the first and the second resistor have the same value. 10. Gate device according to claim 9, characterized characterized in that the plate in question is square and the four electrodes mentioned have the same dimensions and are attached symmetrically. 11. Gate device according to one or more of the preceding claims, characterized in that the core concerned from one Material with a rectangular hysteresis loop. 12. Gate circuit according to claim 11, characterized in that the core concerned from Ferrite is made. 13. Gate device according to claim 1 or 2, characterized in that the plate in question in a polarizing magnetic field has a magnetoresistance effect and that a Excitation current is supplied to the mentioned pair of electrodes, so that the mentioned signal at Presence of the mentioned magnetic field and, in the absence of it, not after the mentioned one Terminal pair is transmitted. 14. Gate device according to claim 13, characterized in that a good or not to be transmitted electrical signal is superimposed on the relevant excitation current. 15. Gate device according to claims 3 and 13, characterized in that said excitation current is fed to the electrodes of the mentioned pair of electrodes. 16. Gate device according to claim 13, 14 or 15, characterized in that the distance between the electrodes of the mentioned pair of electrodes a branch of three further impedances comprehensive electrical bridge forms, which is fed with an excitation current via a diagonal is, while the aforementioned output terminals with the other diagonal circle of the Bridge are connected in such a way that a relatively small change in resistance of the mentioned Distance disturbs the equilibrium of the bridge and a relatively high voltage on the relevant terminal pair brings about. Considered publications:
German patent specification No. 926 885. 1 sheet of drawings © «09 678/145 11.5 *