DE1081698B - Arrangement for moving information or groups of information in a chain step by step - Google Patents

Description

GERMAN

The main patent relates to an arrangement for shifting information step by step or groups of information in a chain with links connected in series, in which each Chain link consists of two parallel branches, one of which contains a two-pole, the other of two possible resistance states and, with regard to its respective resistance state, of the history of the individual chain link is dependent, while the other parallel branch has a charging rectifier and a capacitor contains, which has a discharge circuit to the next element. This component with two possible resistance states, a magnetic core with a rectangular hysteresis loop is preferred, which is provided with only one winding.

The present invention achieves a substantial improvement by starting with the introduction a direct current bias causes a reduction in the coercive force of the magnetic cores. By this measure, magnetic cores of relatively high coercive force can be used, such as z. B. Ferrites with a rectangular hysteresis loop. In addition, the premagnetization results in a reduced Energy expenditure for the transport of information from chain link to chain link and thus the possibility of using pulse generators, which are equipped with transistors and get by with relatively low operating voltages.

In the interest of the smallest possible spatial configuration of the ones described in the main patent Magnetic chains appear to use ferrite cores, also with rectangular hysteresis desirable. These ferrite materials differ from those previously used for the same purpose metallic alloys with significantly smaller dimensions have a higher coercive force. These however, a relatively high coercive force stands in the way of favorable transmission properties. Therefore it generally increases the effort involved in triggering the chains or shift registers Pulse generators result. But just when using these magnetic elements is an equipment the pulse generators with transistors are highly desirable; this both for reasons of low space requirements and especially because of the long service life of transistor circuits.

The inventive introduction of a direct current bias for a magnetic chain register in a magnetic core register, as it is laid down in the main patent, has the effect of an apparent reduction in the coercive force with a da arrangement
to move it step by step

of information
or information groups in a chain

Addendum to patent 1,058,285

Applicant:

Kienzle Apparate GmbH,
Villingen (Black Forest)

Gerhard Wolf, Munich-Solln,
has been named as the inventor

with associated saving of energy for transporting the information.

Such a direct current bias is advantageous because the coercive force of a Magnetic core only interferes with the magnetization reversal in one direction, namely when the previous one Magnetic core originating and temporarily stored in a capacitor information in the subsequent magnetic core is to be transferred. In contrast, the process of "querying" is one Magnetic core by a shift pulse with ejection of the information in the direction of the next core uncritical. Permanent direct current magnetization is therefore sufficient in one direction, in such a way that this corresponds to the process of transferring the Information to the next core is aligned in its effect. It goes without saying that an excessive direct current bias would lead to self-excitation of the chain and therefore must be avoided.

It is advisable to use about half of the existing coercive force through such a direct current bias to compensate. Here, an extremely stable operation can be realized that Improve the useful-to-interference ratio and save shift pulse power.

An embodiment of the invention shows the arrangement shown in the drawing. This represents a counting chain with 10 links in cooperation with a transistor pulse generator, this Arrangement, for example, as a counting device or a program-controlling element. used. . will can.

009 509/203

The chain is composed of .den magnetic cores 10 to 19, which are made of a material with a rectangular shape Hysteresis loops exist. These magnetic cores have windings 20, 21, 22 to 29 to Purpose of transporting the information from chain link to chain link according to the type of the main patent. It it is assumed that there is information in the magnetic core IO saved. A pulse on line 60 results in the inductive counter voltage on the winding 20 a charge of the capacitor 30, which then via the resistor 50 forwards this information via the winding 21 to the following magnetic core 11. Through the impulse on the line 60, the information in the magnetic core 10 is deleted at the same time. By a A series of pulses on pulse line 60 therefore becomes one as described in the parent patent Information shifted step by step from chain link to chain link.

The magnetic chain shown in the drawing is a decadic counting chain made up of two different ones Types of magnetic cores composed with rectangular hysteresis loop. The one with the value zero Corresponding magnetic core 10 is made with rectangular hysteresis material in the form of a larger toroidal core executed. This toroidal core 10 carries windings 20 and 120. It is located at the point of the ring closure of the decadic register and therefore has two identical windings, with winding 120 completes the ring closure of the register and a necessary galvanic separation of the Circles effects.

The only reason why the magnetic core 10 is larger and selected from a different material is because its double Wrapping requires a larger changing room.

The magnetic cores 11, 12, 13 to 19, however, are smaller in size and should be made of magnetic material also exist with rectangular hysteresis, but one relative to the core 10 have greater coercive force. The direct current bias is left on these magnetic cores 11 to 19 act to reduce the coercive force, whereas the magnetic core 10 of the register can be excluded from this bias. A direct current source is used for the premagnetization 110 provided. The auxiliary flow is from part 113 of the source 110 via a line 116 through the Windings 29 to 21 and from there always in the direction of arrow 109 via a resistor 105 to Source 110 returned.

This auxiliary stream supports the transmission of information in the cores 11, 12 to 19.

For a better understanding of the effect of this current, the following should be stated:

Assuming that the capacitor 31 is charged by ejecting information from the magnetic core 11 by a shift pulse on the pulse line 60 results via the resistor 51 and the Winding 22 of the magnetic core 12 a current flow, which the magnetic core 12 by remagnetization to bring in a position that corresponds to the storage of information in this core. To im Magnetic core 12 to bring about this effect is through the winding 22 or through the resistor 51 a minimum current is necessary, which is due to the coercive force of the magnetic core 12, its iron path length and its winding is given. If the charging voltage of the capacitor falls below 31 a certain minimum value, which is caused by the current in the winding that overcomes the coercive force 22 and whose series resistor 51 is given, no effect is produced in the magnetic core 12. Therefore the efficiency of the transmission suddenly drops to zero. The charging of the capacitor 31 are proportionate in terms of the design of the magnetic circuits and the pulse current sources narrow limits set. By introducing the additional auxiliary direct current through the windings 21 To 29 of the magnetic cores 11 to 19, this minimum charging voltage of the capacitor 31 becomes essential reduced, so that even with a lower power-wise design of the pulse source still a flawless one Information transfer comes about. Of particular interest here, however, is the Effect of this pre-magnetization on the useful-disturbance ratio of the register. The windings 20 to 29 are not only coupled to the flow of the rectangular hysteresis material, rather it results through enclosed air cross-sections (leakage induction

ao activities) or reversible components from the hysteresis of the magnetic cores themselves a self-induction, which comes into effect regardless of information contained in the magnetic core. These undesirable Self-inductions together with the pulses on line 60 then also result in one inductive EMF interference when no information is stored in the magnetic core. A similar effect also causes the ohmic resistance of the windings 20 to 29. The greater the amperage or the Power of the shift pulse generator is maintained, the greater are the unwanted Self-induction occurring motor voltages. It succeeds by introducing direct current bias To reduce the power requirement for the shift pulses, this results at the same time a reduction in the interference amplitudes in relation to the useful amplitudes corresponding to the information. This effect contributes significantly to increasing the stability of such registers.

The direction of the auxiliary bias current through resistor 105 and windings 21 to 29 must run in the opposite direction to the displacement current. This results from the fact that the resistor 105 is a lower voltage than at point III7.

In a further refinement of the present arrangement, point 117 of the magnetic chain is therefore attached to a Tap of the power source 110 connected. During the (positive) Current in the pulse line 60 runs from left to right in the drawing, the auxiliary magnetizing current runs from right to left, from point 117 via resistor 105 to current source 110 (Arrow 109).

The source for the pulses on line 60 required for shifting information in the chain is im illustrated embodiment, a generator 101. This generator, a shift pulse generator, has a blocking oscillator with transistor and magnetic core with rectangular hysteresis loop, which is connected to its Output winding a power transistor 102 controls. The DC power source 110 supplies its Part 111 the generator 101 with operating power. This generator 101 can either be via a terminal 103 triggered with positive pulses or with negative pulses via a second terminal 104 and is designed in such a way that that each trigger pulse via one of the terminals 103 or 104 results in a displacement pulse triggers via the power transistor 102 to the pulse line 60.

A 2? C combination 106 is provided in the impulse line 60 between the first winding 20 and the generator 101 in order to avoid disruptive effects on the generator 101. The IC element 106 consists of a capacitor 107 and a resistor 108 and fulfills the following tasks: The circuit via the windings 20 to 29 has a predominantly inductive character. The self-inductions are made up of the parts of the rectangular hysteresis loop and the reversible parts or the air induction of the windings. If one observes the current course of the shift pulse 61 on the line 60, one finds an almost triangular current course. When information is transmitted as a result of a shift pulse, the inductive counter-voltages disappear from the rectangular hysteresis loop towards the end of the shift pulse as a result of the temporary saturation of all magnetic cores in the negative direction. This reduces the counter voltage between the input of the chain on line 60 and output 117, which results in an even steeper rise in current. The charging of the capacitor 107 counteracts this. The capacitor 107 is in the discharged state at the beginning of the shift pulse. Due to the current flow on the line 60 during the shift pulse, the capacitor 107 is charged, which more and more counteracts the increasing current flow. The voltage on the input line 60 of the chain is therefore reduced by the voltage drop on the capacitor 107. As a result, the current peaks, which could cause an overload of the transistor 102, are initially intercepted. At the same time makes this i? C combination 106 ensure that the emitter-collector voltage remains small during the opening period of the transistor 102, the transistor 102 thus operates in "knee voltage". Thus, both current and voltage relief of the transistor 102 is achieved even during the opening time.

A further risk to transistor 102 can be caused by the switch-off voltage of the magnetic chain - caused by the reversible components and air induction of the windings at the moment of the shift pulse trailing edge. The fact that the current peak which occurs on line 60 after the magnet cores 10 to 19 is saturated has already been reduced, a reduction in the switch-off peak voltage is brought about. In addition, at the moment of switch-off, the capacitor 107 is charged to its highest value, specifically with a polarity which counteracts the switch-off EMF of the coils.

During the opening time of transistor 102 , it is kept in knee tension by the effect of the i? C combination and dangerous current peaks are intercepted. At the moment when the transistor 102 is blocked - i.e. when the shift pulse trailing edge occurs - the charging of the capacitor 107 counteracts the inductive switch-off peaks of the windings 20 to 29 and thus avoids disruptive repercussions on the generator 101.

The resistor 108 has the task of discharging the capacitor 107 in the pulse pauses. The decay time must be chosen so that the capacitor 107 is almost completely discharged between two counting steps with certainty. Likewise, the charging of the capacitor 107 increases the turn-off speed of the power transistor 102. This takes place in that the effect of the self-induction of the windings 20 to 29, which maintains the pulse current even after the transistor 102 has been turned off, is compensated by the counter voltage of the capacitor 107. In addition to relieving the load on transistor 102 in terms of voltage, the capacitor results in a shorter switch-off time for the displacement pulses, which further increases the efficiency of the chain.

The magnetic state existing in the register can be erased by a relatively long current surge via the pulse line 60 . This pulse must be several times longer than the shift pulse. This can be brought about, for example, by fading in a control signal via a terminal 115 at the emitter of transistor 102 . The length of the erase pulse is not limited, so that pure direct current erasure can also be used.

Claims (8)

Patent claims: 1. A device for improving the operation of an arrangement for incrementally move information or the information groups in a chain, additional to patent 1,058,285, characterized in that from a direct current source (110) depending on a winding of each magnetic core (10 to 19) a bias current in is supplied in such a way that this current affects the magnetic flux of the cores (10 to 19) in a direction opposite to that obtained by the shift pulse. 2. A circuit according to claim I, characterized in that the direct current source (110) is connected to the sliding windings (20 to 29) of the chain. 3. Circuit according to claims 1 and 2, characterized in that the bias current is chosen so that it has a predetermined part of the coercive force of the magnetic material in one direction. 4. Circuit according to claims 1 to 3, characterized in that a decadic In the chain, the magnetic core (10) corresponding to the value zero does not receive a bias current. 5. Circuit according to claims 1 to 4, characterized by the arrangement of an RC element (106) which is switched into the pulse line (60) in such a way that there is a charge on a capacitor (107) which compensates for interfering effects and thus away from the pulse source (101). 6. Circuit according to claims 1 to 5, characterized in that a deletion of the Chain can be carried out by a long pulse on the shift pulse line (60). 7. Circuit according to claims 1 to 5, characterized in that a transistor generator (101) is provided as a shift pulse generator. 8. Circuit according to claims 6 and 7, characterized in that the chain is deleted by entering a special control signal in the emitter circuit of a power transistor (102) of the generator (101) . 1 sheet of drawings © OM 5W / 203 5.60