DE1437676C - EXCLUSIVE OR link - Google Patents

Description

The invention relates to an EXCLUSIVE-OR-GliccI, which is used as a storage element, especially in digital storage systems. One such ;; Link has a core made of magnetizable material with a rectangular hysteresis loop and a single hole.

The known memory elements, as described, for example, by RM Ti N and others in the journal IRE-Electronic Computers, September 1960, Si 56 and 57, as Fluxlok technology, are not an EXCLUSIVE-OR element with a single core usable. According to the invention, however, this is made possible by the fact that the core used is subjected to an external, non-annular, permanent magnetic field running perpendicular to its axis and that information A is applied to a first winding which surrounds the core in such a way that its winding plane is perpendicular to the external magnetic field. Furthermore, information B is applied to a second winding which is wound through the hole in the core, and the output signal is picked up at a third winding which is applied in the same way as the second winding and which is arranged in such a way that its winding plane is exposed to the external magnetic field is not penetrated.

Appropriately, the outer Magnetleid 'son is formed by a permanent magnet on the Core results in a magnetic field of 25 to 100 oersteds.

Becomes the EXCLUSIVE-OR element after the establishment used as a memory element, the LTSth winding sets each bit as a query winding Row 'in series to determine the change in flux at each bit in a perpendicular to the plane of the interrogation field measure and determine if all of the bits that contain a word in memory match a comparison word compare to determine the address of all stored words that matched the comparison word be compared.

To explain the invention, an exemplary embodiment is described with the aid of the drawings. In the drawings is

Fig. 1 is a perspective view of a broken away Part of the core arrangement with several LXCLUSIV-OR gates according to the invention,

F i g. 2 a toroidal core as it is in the arrangement according to FIG. 1 is used on a larger scale,

3 shows the flux vectors in the region Y of the core according to FIG. 2 and their change in direction when abirage pulses are applied with and without an external magnetic field.

Fig. 4 is a block diagram of a device for Execution of the memory function when using the HXCLUSIV-ODHR element according to the invention as Storage element. . ; '.

F i g. 2 shows an annular ferrite magnetic core 30 made of highly permeable magnetic material. Cores of this type are commercially available. An external, non-annular magnetic field 31 is applied to the core 30 so that it runs perpendicular to the axis. The magnetic field 31 generates resulting magnetic fluxes through the core, as indicated by the arrows 32. A write-release clip 33 may be looped around the core at one point to create the desired combination ion. The external magnetic field 31 is insufficient / min to completely change the resultant of the magnetic flux induced by the winding 33. The interrogation winding 34 runs in the manner of a solenoid around the core 30 so that it lies in a plane perpendicular to the magnetic lines of force 32 of the external magnetic field 31. In measuring the flux changes in the core 30, it is only necessary to measure the flux changes in the portion 35 of the core designated as region Y , which is an arcuate portion of the core below the sensing winding 36 and perpendicular to the

ίο represents magnetic field 31. The scanning winding 36 runs around this core area and senses all flow changes in it. The core 30 'of FIG. 2 shows exactly one of the cores 22 in FIG. 1.

From Fig. 3 it can be seen the need to use an external magnetic field to effect the EXCLUSIVE-OR function. The upper half of FIG. 3 shows the flux vectors in the region Y of a toroidal core which is not subject to the external magnetic field. An upward-pointing flux vector represents an information bit B , while a downward-pointing flux vector represents an information bit 27. When information flows through an interrogation winding, it induces a magnetic field in region Y in the direction shown by arrows 40. Def flux represented by the arrows 40 tries to turn the resultant B of the magnetic flux in the area Y of the core at the angle Φ λ with the designation 41 to the right, and causes a flux change in the area Y in the downward direction, Ι Φ. Conversely, in the case of a bit 7? Stored in area Y , which is applied via the query winding, the Zf flux vector is shifted to the right and causes a similar change J Φ in the flux, but in an upward direction, which is indicated by arrow 42. The reversal succeeds if the flow B or ~ B present in the area Y ■ of a core is queried with /! Pulses by the query winding. The flow B is changed again in the downward direction, as indicated by the arrow 43, while the flow Ti changes in the upward direction according to the arrow 44. This means that only the functions AB-VÄB and ΑΉ + AB can be obtained. None of these functions is the EXCLUSIVE-OR function.

It can be seen from both halves of FIG. 3 that the flux vectors B and B are shifted by equal values in accordance with the angle Θ which represents the amount of the shift which occurs because of the external magnetic field. In this situation, the information flowing through the interrogation winding to generate a magnetic field indicated by arrows 50 causes displacements of the B and 77 flux vectors in region Y in the direction indicated by angles θ , which in turn causes flux displacements .1 Φ in the downward direction for the flow B and upward for river B as indicated by arrows 51 and 52. It can thus be seen that the flow changes according to the arrows

^fi "51 and 52 are greater than without a magnetic field, but occur in the same directions, which correspond to the situations in the case where no magnetic field is applied. The change occurs when 7f pulses pass through the interrogation winding,

^r Ki where the external magnetic field still deflects the B and 77 resultants ei in the same direction. At this point in time the // and // resultants move to the left by the value of the angle \, like this

that the resulting flux change, 1 Φ for the ß-flux in the upward direction according to the arrow

54 runs, while the resulting flux change for the B-flux is downward according to the arrow

55 is directed. This means that the following functions can be sampled if the external magnetic field is applied:

AB + 7CB and ΛΈ + ~ ÄB

or in other words this gives the functions EXCLUSIVE-OR, one of which is to perform the corresponding memory information is necessary. The use of the external magnetic field thus enables cross-field switching technology. the one interrogation winding placed around a toroidal core like a solerioid used to provide the EXCLUSIVE-OR functions for non-nullifying reads to be queried. This type of information from a single toroid using cross-field switching technology is not possible without an external magnetic field, as can be clearly seen in the upper half of FIG.

The invention shows that the external magnetic field is approximately ten times stronger than the interrogation magnetic field must be in order to achieve the desired effect according to the invention. The external magnetic field can be between 1 and 50 times larger than the interrogation magnetic field. The greater strength of the external magnetic field allows shifting the resultant of the magnetic flux of the Kerns, which allows the interrogation magnetic field to determine the desired logical functions. The outer Magnetic field should apply a magnetic field strength of 20 to 100 Oersted to the nucleus, in order to achieve the desired Get results. If a permanent magnet delivers the field, it can touch the core, to provide the desired magnetic field strength when the magnet has such a low permeability has that the contact with the core causes no deviation of the field distribution in the core.

Another advantage of the externally created Magrietfeld, which is not only for corresponding Memory operations applicable is the gain of the output voltage produced by the sense winding 36 in FIG. 2 has been established. The switching time for writing and reading is also decreased. This results in a higher signal-to-interference ratio and thus a more effective and usable, light-extinguishing element received. These benefits can be general to other types of permeable single or multiple hole magnetic cores are used.

Any suitable means can be used to provide the external magnetic field. For example In addition to a permanent magnet, the field can either be generated by a current through the interrogation winding or created via another conductor. It is important that the exterior Magnetic field runs parallel to the query matfcld.

Such an EXCLUSIVE-OR-Glicd can now be used as a storage element, for example in a storage unit as shown in FIG. 1. The base of this storage unit 20 is a permanent magnet which is a necessary element and the only feature of the structure. A thin recording layer 21 may be applied to it in any suitable manner. Storage requirements result from a plurality of ferrite toroidal cores 22 which are aligned in columns 23 and rows 24 and are thereby lulled in their position in that a part is slightly embedded in the receiving layer 21. The layer 21 can be an insulator in order to build up the correct external magnetic field on the core. The primary purpose of layer 21 is to provide a means for properly aligning cores 22 with plate 20. Columns 23 represent a bit alignment from bit one to bit η , while rows 24 represent the word alignment from word one to word η . The bit with the

ίο the highest designation of the word one is thus in a kernel 25 on the leftmost side of the word one.

In order to write information into the cores 22 or to extract information from them, each column 23 is provided with a + or - '/ »- line 26. These H or - '/ »lines are passed through each bit-aligned core in each column 23. Since this + or - Ai turn can produce enough current to produce flux changes in the cores 22, each core row 24 will be stranded with a ¹ h and a reset line 27. A special core 22 can be provided with the desired bit information in a simple manner by energizing a special ' ¹ IH and reset line 27 and a special + or -'Ai write line 26. The resultant of the magnetic flux is thus not placed in a core 22, unless its special - \ - k- χχηύ reset line 27 and its -! - or --Ai write line with the -I- or - '/ 3-write line , which is excited in the + direction, are excited. Thus, a one is written into a core 22 when a flux resultant is induced by a ² Ii and a Vs write signal so that this resultant is in the right direction. Conversely, zero is written through the reset part of the '- / »- and the reset line 27, which causes a resultant in the opposite direction. Before words are written to memory, all cores are reset to zero.

The information stored as bits, which are represented by flow resultants in the cores 22, can then be queried in that each column of the cores 23 has a core that is in a column surrounded by an interrogation line 28 is located. These lines 28 must be parallel to Base plate 20 be arranged so that they have an ab-

'Question-generate magnetic field that is parallel to the outside Magnetic field that emerges perpendicular to the surface of the base plate. To better this effect It is intended to make the sense line from a conductive strip that is solenoid-like wrapped around the center of each bit-aligned core in each column 23.

To determine the bit of information stored in each core 22 while the interrogation magnetic field, which is generated by a current flowing through the interrogation line 28 is attempted the invention to use a scan line 29 running through and around each core in each aligned Row that represents a word. For the storage unit to work properly, it is essential that that the scan lines in each core in an arcuate portion of the core opposite the Part of the scanning flux effective next to the base plate 20 or perpendicular to the magnetic field change, as will be explained later.

In summary, it can be seen that the cores 22 in bit-aligned columns and rows, the words

l 437

represent, are arranged. The information is presented as the resultant of the magnetic flux in the Cores written by write lines passing through each bit-aligned column and bit-aligned Go through the row so that each core is individually set to the desired combination can. An interrogation line is provided at each bit aligned column and creates an interrogation magnetic field to provide cross-field switching technology to non-negatively change the flux in the core. This interrogation magnetic field must be parallel to that generated by the permanent magnet base plate 20 Magnetic field. A sensing winding 29 is located on each core to detect flux changes in the Determine arcuate part of the core perpendicular to the interrogation field and the external magnetic field. The corresponding storage function in a storage system is now the function in which a Comparison word is compared with the respective stored word, a comparison of either the whole word or just a bit that occurs during a normal read cycle. The appropriate memories can be used to determine where a comparison has been made between a comparison word coming from outside and an unknown word in memory or to determine the value of the comparison made. The saved word can partially or intermittently covered, leaving only a fraction of each word for comparison is brought with the same parts of a comparative word.

Claims (5)

Patent claims: 1. EXCLUSIVE-OR element with a core made of magnetizable material with a rectangular hysteresis loop and a single hole, characterized in that the core (30) is subjected to an outer non-annular permanent magnetic field (31) extending perpendicular to its axis, that information A is applied to a first winding (34) which is arranged around the core (30) in such a way that its winding plane is perpendicular to the external magnetic field (31), that information B is applied to a second winding (33) which is transmitted through the Hole of the core is wound, and that the output signal is taken from a third winding (36) applied in the same way as the second winding, which is arranged such that its winding plane is not penetrated by the external magnetic field (31). 2. EXCLUSIVE-OR element according to claim 1, characterized in that the external magnetic field (31) is formed by a permanent magnet will. 3. EXCLUSIVE-OR element according to claim 2, characterized in that the permanent magnet on the core has a magnetic field of 25 to 100 oersted equals. 4. EXCLUSIVE-OR element according to one of the preceding claims, characterized by use as a storage element. 5. EXCLUSIVE-OR element according to claim 4, characterized in that the first winding (34) as a query winding puts each bit of a row in series to reflect the change in flux at each bit to measure in a perpendicular to the plane of the interrogation field and to determine if all the bits which contain a word in memory, compare with a comparison word to get the address of all stored words to be compared with the comparison word. 1 sheet of drawings