DE1133161B - Circuit arrangement for quantitative reading in magnetic memory cores - Google Patents

Description

Circuit arrangement for quantitative reading in magnetic memory cores Arrangements are already known in which information is stored in magnetic storage cores can be stored and then removed again. This information will be by setting the magnetic state of the memory core used accordingly held. In certain arrangements it is envisaged that a number of different States, i.e. different levels of magnetization of the relevant memory core, can be adjusted. In this way it is achieved that in the same memory cores one of several different pieces of information can be entered as required. When reading the information one proceeds in such a way that one in several Steps, a gradual remagnetization of the storage core with the help of current pulses takes place until the memory core becomes saturated. The number the current pulses required for this serve as a measure of the original state of magnetization and thus as an indication of the information stored. It is here a quantitative reading process. When reversing the magnetization of a magnetic Kernes shows that the corresponding to the magnetic field strength generated in each case Force flux density in the storage core does not appear spontaneously, but only with one certain time lag. The resulting magnetic field strength is below otherwise the same circumstances are proportional to those during the supplied current pulse existing amperage. Because there is also a certain technical limit for the applicable If the current strength is present, the current pulses used for magnetization cannot be used make it as short as you like. It therefore inevitably takes a certain amount of time before the reading process is finished. This time is used as storage cores with gradual reversal of magnetization used counting chokes so large that in connection with this use of Counting chokes for storage purposes in telecommunications technology are already disruptive and not permissible time losses occur.

The invention now shows a way how to make this waste time almost can avoid completely. This is e.g. B. extremely important in long-distance dialing technology, because in this way the occupancy time of central switching links is essential can reduce, allowing them to perform more mediation jobs.

The invention is therefore a circuit arrangement for quantitative reading of the information content represented by its magnetic state a magnetic storage core. This reading process is characterized by that for the determination and binary-coded representation of the magnetic state of a Memory core this successively supplied different sized magnetic reversal pulses which each result in magnetization reversals by the same number of steps, like the largest, the second largest, etc. down to the smallest value of the provided binary representation correspond, and that, if the magnetic reversal pulse is only sufficient for a reversal of magnetization to a state of saturation or less, the binary number assigned to its size is marked in an output device is, and that in each case when the magnetic reversal pulse is greater, the before The information available in the storage core after the magnetization reversal as a result of the withdrawal is retained in a magnetic auxiliary core for further query, whereby after Repetition of these process steps those binary digits of the output device are marked, which is the binary-coded representation of the originally in the memory core correspond to the decimal-coded representation marked by its magnetic state.

The number of realizable magnetic states between the two different magnetic saturation states may be a maximum of equal to that caused by the Output device in binary representation be detectable numerical value.

It is also shown how the magnetic reversal pulses are obtained and in what way the auxiliary kernel or, if necessary, several auxiliary kernels to are using. Circuit arrangements are also shown, with the help of which the binary code character is converted into another code character with the structure »2 of 5 «can be implemented.

The circuit arrangement according to the invention shows how the Information stored in the memory core is read and represented by a binary code character can be represented. The individual digits of the binary number become very fast and in the correct order, d. H. starting with the highest number of binary digits, won, step by step, each with the relevant process step, and are therefore immediately available for further use, e.g. B. for onward delivery to a recipient, ready.

If you would by gradually reversing the magnetization of the memory core up to Count the number of previously entered pulses for the respective saturation state and at the same time switch a four-stage binary counting chain through its operating position after the counting process has ended, the associated binary number is displayed, so one would have to wait to pass on the first digit of the binary number until the entire counting process is finished. The operating position of the individual stages of the binary counting chain namely changes during the counting process. Only after it has ended do you enter the final operating positions on the stages. Since, as already mentioned, the gradual Magnetization of the memory core and thus the counting process from physical Reasons can only go on at a limited speed, therefore, passes, in particular if a long series of impulses had been stored beforehand, a fairly long one Period of loss before the output of the binary code character can begin. This loss period is avoided by the circuit arrangement according to the invention, since the transmission of the individual character elements of the binary code character to a recipient immediately can be started at the end of the first process step. The recipient can start the evaluation as soon as the first drawing element arrives.

There are already arithmetic instructions for converting decimal numbers known in binary numbers. According to these arithmetic instructions are, among other things, either Make multiplications or divisions, or there are subtractions by numerical values depending on the size of the number to be converted. These arithmetic instructions are therefore completely different from that of the circuit arrangement according to the invention lying arithmetic instruction. According to the invention, it is therefore not necessary to perform multiplications, Realizing divisions or subtractions with numerical values that have not yet been determined. The circuit arrangement according to the invention can therefore with relatively little Expenditure on technical means can be carried out.

Fig. 1 shows a circuit arrangement with which the inventive Reading process can be handled; 2 and 3 show two circuits for implementation of the binary code character.

First, the reading method according to the invention is explained in detail with reference to the circuit arrangement shown in FIG. The memory core D serves as the actual information memory. It has the input winding I, the query winding 1I and the output winding III. The pulse generator PG serves here as the source for the pulses to be stored. If it is connected to input winding I via contact p , pulses are fed in. At the beginning of the storage process, the memory core D must be in the one magnetic saturation state. If several identical pulses are supplied, the magnetization state is changed in steps according to the number of these pulses. Instead of several pulses, a single pulse could be supplied in such a size that an equally large reversal of magnetization is achieved. In addition to the memory core D, the auxiliary cores H 1, H 2 and H 3 are also provided. If the number of magnetization levels provided can already be specified by a four-digit binary number, three auxiliary cores are sufficient, otherwise additional auxiliary cores would have to be provided. For an n-digit binary number output, n, -1 auxiliary kernels are required. The input winding I of the auxiliary core H 1 can be connected to the output winding III of the memory core D via the normally open contact s13. The input winding I can be connected to the voltage Ul via the contact s14, as a result of which the magnetic core is brought into a magnetic saturation state. The auxiliary core HI also has the query winding II and the output winding 11I. In the same manner as the auxiliary core H1 the memory core D is the auxiliary core 1. H2 associated with the auxiliary core H and a contact, here the normally open contact n31, connectable to the auxiliary core H1. The auxiliary core H3 is assigned to the auxiliary core H2 in the same way. In addition, the query core A is still available. It is used to generate interrogation pulses in the required gradation in terms of size. The interrogation core A has the windings I and II. The winding I can be connected to the voltages UL or Um via the contacts s01 and s02. If it is alternately applied to these two voltages, it is each time brought from one magnetic saturation state to the other. The entire winding 1I, which serves as the output winding, therefore delivers every time the winding I z. B. the voltage Um is applied, a pulse with a certain size and direction. Fluctuations in the voltages Um have no influence on the supplied pulse, provided that the voltage Um is so great that a complete reversal of magnetization is effected, as the integral of the pulse amplitude remains constant over the pulse duration. This integral is decisive for the pulse size. The output winding 1I has several taps. The pulses that are smaller than the pulse delivered by the entire output winding can be taken from these. A suitable choice of these taps can be used to give these smaller pulses the desired size. Any sections of the output winding can be connected to the distribution line v via the contacts s12, s22, s32 and s42. Via the contacts 11, s21, s31 and s41, the interrogation windings of the other cores, i.e. the cores D, H1, H2 and H3, can be connected to the distribution line v in any way. By actuating these contacts s12. .. s42, s 11 ... s41 any allocation of interrogation pulses of the desired size to the cores D, H1, H2, H3 is possible. A relay R of the control device N is also inserted into the circuit in which the winding II of the interrogation core A is located. Its task is described below. After connecting the winding 1I of the interrogation core A to the winding II of the storage core D or a winding 1I of the auxiliary cores H1 to H3, a magnetic reversal pulse from the interrogation core A is fed to the core concerned for remagnetization, as already mentioned. There are now two different options for the remagnetization process itself. In the first operating case, the magnetization reversal pulse is not sufficient for a complete magnetization reversal of the storage core or auxiliary core, which leads to the saturation state. In this case, the inductance of the storage or auxiliary core is effective for the entire duration of the remagnetization pulse in the circuit through which it passes and prevents the amplitude of the remagnetization current from exceeding a certain level. In the second operating case, the magnetization reversal pulse is greater than would be required to reach the saturation state, so that after the complete magnetization reversal of the memory or auxiliary core has been achieved, the magnetization reversal pulse continues to rise. When the magnetic saturation state of the storage or auxiliary core is reached, the change in the magnetic flux ceases and the previously induced counter voltage in winding II of the storage or auxiliary core disappears. As a result, the current strength of the magnetic reversal pulse now assumes a significantly larger value. This fact can be used to make a switching means inserted in this circuit respond. In the circuit according to FIG. 1, this is the relay R belonging to the control device N. In the operating case considered first, the relay R receives fault current and, in the second operating case, response current. Instead of a relay, another, correspondingly acting and suitable switching means can also be used.

In the course of a reading process, the control device N actuates the associated contacts n 1, n2, n33 and n43 depending on the information read from the cores Binary number can be marked with the place values 8, 4, 2 and 1.

The voltage N is optionally applied to the relevant terminals via the contacts n 1, n 2, n 33 and n 43. If the terminal in question is potential-free, this may mean the number 0, and if it has the voltage U, then this may mean the number 1. The control device N also includes the contacts n31, n32, n41 and n42. Their meaning is given in the description of the function of the reading device. The contacts 01, s02, s 11 ... s41, s12 ... s 42, s 13 and s 14 are actuated by the control device N and are used to control the functional sequence in the reading device.

The operational sequence in a reading process will now be described. It may be made in the memory core D storage, the z. B. nine Corresponds to number writing pulses. It therefore has a reversal of magnetization in the memory core D. from the one magnetic saturation state took place by nine magnetization levels. This information content can now be read from the memory core and in the form of a Binary number by marking terminals 8,% 1, 9 and? the output device to represent. For this purpose, the control device N controls the reading device to operate existing contacts in the correct order.

The reading process takes place in several cycles. At the beginning of the reading process, the interrogation core A and the auxiliary cores H 1 to H 3 may be in the magnetic saturation state, which can be established by applying the voltage Ul across the contacts 01, s 14, n 32 and n 42 .

The greatest significance of the four-digit binary number provided here corresponds to eight magnetization levels. During the first cycle, a magnetization reversal pulse is therefore initially supplied to the memory core D for the purpose of reading, which pulse can perform a magnetization reversal by eight steps. For this purpose the contacts 11, s12 and s02 as well as s13 are closed. The interrogation winding II of the memory core D is connected to the entire winding II of the interrogation core A via the contacts s 11 and s 12. When the contact s 02 is closed, this entire winding 1I supplies an interrogation pulse which corresponds to eight reversal of magnetization steps. By closing the contact s02, the winding I of the interrogation core A is connected to the voltage Um , as a result of which the interrogation core is magnetized. The resulting interrogation pulse influences the memory core D and approaches its magnetic state by eight magnetization levels to the one saturation state, which, however, is not reached in this assumed example, since the memory core D had previously been remagnetized by nine magnetization levels. Its magnetic state is still one level of magnetization away from this saturation state. The relay R of the control device N therefore receives fault current and does not respond. The binary number digit assigned to the first reading cycle, that is, the one with the priority value 8, is marked in the output device by connecting terminal 8 via contact n 1, which is controlled by switching operations in the which are not to be explained as a result of the failure of the relay R to respond Control device N, goes into working position, to which voltage U is applied. The number 1 is therefore at this binary number. The contact s 12 is opened again, controlled by the control device N, and so is the contact s02. By temporarily closing the contact s 01 , the interrogation core A is returned to its original magnetic saturation state. Before the interrogation process just described for the memory core A, the control device established a connection between the output winding III of the memory core D and the input winding N of the auxiliary core H 1 via the contact s 13. The storage core and the auxiliary cores and their corresponding windings are each identical to one another. When the storage core D was reversed, the auxiliary core H 1 was therefore also reversed, namely by exactly as many magnetization levels as the storage core. Since in the first cycle of the reading process described above, the magnetic reversal pulse supplied to the memory core was not greater than is necessary to achieve the magnetic saturation state, which could be determined by the control device as a result of the relay R not dropping out, the remagnetization of the memory core D Information entered at the same time in the auxiliary core H 1 is no longer required for the further reading process. The contact s13 is therefore reopened by the control device N, and by temporarily closing the contact s14, the voltage Ul is temporarily applied to the winding I of the auxiliary core H 1, whereby the latter is restored to its original magnetic saturation state.

The second cycle of the reading process now takes place. This time the contacts s11, s22 and s13 are closed first. Then contact 02 is closed. The interrogation pulse this time fed to the memory core D is, since it is only supplied by part of the winding II of the interrogation core A, smaller than in the first cycle, and this time it corresponds to four remagnetization stages, i.e. the value of the second largest binary digit. Since the storage core D only needs a reversal of magnetization equal to one level of magnetization in order to reach the magnetic saturation state, the excess bias current causes the relay R of the control device N to respond. As a result, the contact n2 is not closed this time, and a terminal of the output device is therefore not marked. This time, the information entered in the auxiliary kernel H1 is not removed again. Contact s14 is therefore not temporarily closed. Just as in the storage core D, a reversal of magnetization by one step has taken place in the auxiliary core H1, and this reversal of magnetization is initially retained. The contacts 11, s22, s13 and s02 are now opened again. By temporarily closing the contact s01, the interrogation core A is returned to its original magnetic saturation state.

The third cycle of the reading process now takes place. This time contacts s21 and s32 as well as contact n 31 are closed first. Then contact s02 is closed to generate the interrogation pulse. It is supplied from such a section of the winding 1I of the interrogation core A that it can cause a reversal of magnetization by two magnetization levels. However, since there is only one reversal of magnetization by one step in the auxiliary core H1, the magnetization reversal pulse supplied to it is greater than is necessary to achieve the magnetic saturation state. Therefore, the relay R of the control device N responds when this remagnetization pulse is supplied. As a result, a terminal of the output device is not marked this time either. The auxiliary core H1 was returned to its original magnetic saturation state by the magnetic reversal pulse. At the same time, however, the auxiliary core H2 has been remagnetized by one step, since contact n31 was closed during the interrogation process. By temporarily actuating contact s01, the interrogation core is now returned to its original magnetic saturation state. Contacts s21, s32 and n31 are opened again.

The fourth cycle of the reading process is now running. To do this, contacts s31 and s42 are first closed and then contact s02. The interrogation pulse generated this time is just so large that it can cause a reversal of magnetization by one magnetization step. The auxiliary core H2 is therefore just being returned to its original magnetic saturation state. The relay R of the control device N therefore does not respond this time. A marking is therefore made on the output device, specifically on that terminal which belongs to the binary number point assigned to this clock. This is terminal 1. The contact n 43 is therefore closed. At terminals 8, 4, 2 and 1 of the output device, the binary number 1001, which corresponds to the decadic number 9, is therefore identified as the result after the four cycles of the reading process have elapsed. At the end of the reading process, contacts s42 and s31 are opened again. With the help of a temporary actuation of the contact s01, the interrogation core is returned to the original magnetic saturation state. This means that all cores are back in their original state.

The four cycles of the reading process have to be according to the regulations of the method according to the invention handled. Depending on the beginning The relay has a magnetic state that is present in the memory core during the reading process R of the control device N addressed in the individual cycles of the reading process or not addressed. After that, the further sequence of the next has then in each case Clock directed. It was also dependent on whether there was a terminal of the output device marked or not. If the memory core D If only one magnetization step had been reversed, the relay would R only respond at the fourth cycle of the read process, and it would therefore be the information can be passed on to the auxiliary core H3. In this reading example all three auxiliary cores provided are required.

You can also design the sequence of the bars a little differently by provides that information passed on to the auxiliary kernel H 1 before the expiry of the next clock is returned to the memory core D. The one from the query core A delivered magnetic reversal pulse is then returned to the memory core at the next cycle D feed. When using this measure, only a single auxiliary core is required.

The control device N for actuating the contacts for processing the various cycles of the reading process can be built up using relay switching technology will. There are already relay circuits for handling a wide variety of control tasks was built; so this control task can also be solved in this way. If the speed of the cycle sequence in the reading device that can be achieved with the relay is not sufficient, the relays can also be replaced by electronic means.

In telecommunications technology, there is a lot of effort to find a code for Use flags that allow some control over whether the code character received is correct or not. The code »2 of 5« used. The associated code characters always have five character elements. The drawing elements can each denote one of two different states, so z. B. whether a marking is made has been or not. If the code character "2 of 5" is correct, it contains just two character elements, which denote a mark. Does it contain more or less than two of these Sign elements, then the sign is certainly wrong.

The Fig.2 and 3 show two devices that are used to create a four-digit Binary number, which comprises a maximum of ten counting units, into a code character of the code »2 of 5« to be implemented. The device for repositioning is connected to terminals 8, 4, 2 and 1 of the output device connected.

In the device shown in Fig. 2, the code terminals 8 ', 4', 2 ', 1' and 0 are present, on each of which the relevant code symbol "2 of 5" is represented by marking. The code terminals 8 'and 4' are directly connected to the terminals 8 and 4. The code terminals 2 'and 1' are connected to the terminals 2 and 1 via the contacts k 2 and k 1. The code terminal 0 is at the output of the exclusive mixing gate E, the inputs of which are connected to terminals 8, 4, 2 and 1. The code terminal 0 represents an additional marking point. The coincidence gate K 421 is also provided, the inputs of which are connected to terminals 4, 2 and 1. Its output is connected to the switching device K. The switching device K responds when the output of the coincidence gate K421 is marked, and then actuates the contacts k 2 and k l. The binary numbers for one to ten counting units are now known to be 0001, 0010, 0011, 0 1 00, 0101, 0110, 0111, 1000, 1001 and 101.0. Some of these binary numbers have one digit denoted by the number 1, some two digits and the number 0111 three digits. Each binary number has four digits. In order to get a "2 of 5" code, an additional marker must first be provided, as already described. This marking point must be marked if only one binary digit was designated in the course of the reading process. If two binary digits have been designated, an additional marking is superfluous. If the binary number 0111 occurs, the marking associated with it must be converted into the marking of only two of the code terminals 8 ', 4', 2 ', 1' and 0. The exclusive mixing gate E is used to mark the additional marking point, which is represented by the code terminal 0, via which a marking occurs at the code terminal 0 when one of its inputs is marked. To implement the marking of the binary number 0111, the coincidence gate K421 in cooperation with the switching device K and the associated contacts k 2 and k 1 at the output of the coincidence gate K421 likewise a marking, whereby the switching device K is made to respond, which actuates the contacts k2 and k 1 . The contact k 1 interrupts the connection between the terminal 1 and the code terminal 1 '. The contact k2 interrupts the connection between the terminal 2 and the code terminal 2 'and at the same time forwards the marking of the terminal 2 to the code terminal 8'. In this case, the code terminals 8 'and 4' are marked as the only code terminals. This code character is not present in any other case and can therefore be used for converting the binary number 0111. This shows how the device shown in FIG. 1 converts the previous four-digit binary numbers into the code "2 of 5".

FIG. 3 shows a variant of the circuit according to FIG. The output device also has four terminals here. These are terminals 7, 4, 2 and?. The value of the position belonging to terminal 7 is seven units here. The other places have the same. Significance values as with the four-digit binary numbers considered so far. The numbers for one to ten counting units are accordingly supplied here in the following representation at the four terminals of the output device: 0001, 0010, 0011., 0100, 0101, 0110, 1000, 1001, 1010, 1101. The reading process is the same for this number representation As described so far, with the only difference that the first interrogation pulse is only sufficient for a reversal of magnetization by seven steps instead of eight steps. Even with the numbers obtained in this way, only one place is indicated by the number 1 for some, but two places for some and three places for the number 1101. The conversion of these numbers into code characters according to the code "2 of 5" can be carried out in a very similar manner to the circuit according to FIG. 2 with the aid of the circuit according to FIG. In the circuit according to FIG. 3, the code terminals 7 ', 4', 2 ', t' and 0 are present. The code terminals 7 'and 4' are connected to the terminals 7 and 4, the code terminals 2 'and 1' are connected to the terminals 2 and 1 via the contacts k 2 and k 1. The code terminal 0 is connected to the output of the exclusive mixing gate E in the same way as in the circuit according to FIG. There is also the coincidence gate K721, which has its inputs connected to terminals 7, 2 and 1 and to whose output the switching device K for actuating the contacts k 2 and k 1 is connected. The function of this circuit is quite analogous to that according to FIG. In the case of numbers in which the digit 1 is only present in one place, the code terminal 0 is additionally marked, and in the case of the number 1101 a conversion is carried out in such a way that the code terminals 7 'and 4' are marked.

Claims (13)

PATENT CLAIMS: 1. A circuit arrangement for the quantitative reading of the information content of a magnetic memory core represented by its magnetic state, characterized in that for the determination and binary-coded representation of the magnetic state of the memory core (D) it is fed successively different magnetic reversal pulses, each reversal of magnetization by as much Number of steps result in how they correspond to the largest, the second largest, etc. up to the smallest value (... 8, 4, 2, 1) of the intended binary representation, and that, if the remagnetization pulse only for a remagnetization up to the saturation state or is less sufficient, the binary number digit assigned to its size is marked in an output device and that in each case when the magnetization reversal pulse is large, the information present in the memory core before the magnetization reversal is due to being saved in a magnetic auxiliary core (Hl, H2, H3 ) is retained for further interrogation, whereby after repeating these method steps those binary digits are marked in the output device which correspond to the binary-coded representation of the decimal-coded representation originally marked in the memory core (D) by its magnetic state. 2. Circuit arrangement according to claim 1, characterized in that the remagnetization pulses when magnetizing a special interrogation core (A) are generated, which an output winding (II), which is divided into several sections, which the magnetic reversal pulses can be taken in the intended gradation. 3. Circuit arrangement according to claim 2, characterized in that the memory core (D) has an interrogation winding (II) is provided, which for the purpose of querying one after the other to the various Sections of the output winding (1I) of the query core (A) is connected. 4. Circuit arrangement according to one of the preceding claims, characterized in that as a criterion for whether the magnetic reversal pulse is greater or not than to bring about the saturation state in the interrogated core (D, H 1, H 2, H 3) is necessary, which is only when If the magnetization reversal pulse is larger in the magnetization reversal circuit when querying the particular magnitude of the magnetization current that occurs after the magnetic saturation state has been reached. 5. Circuit arrangement according to claim 4, characterized in that the particularly high magnetic reversal current a control relay (R) is triggered. 6. Circuit arrangement according to claim 5, characterized in that an output winding (III) is provided on the memory core (D) is to which an input winding (I) of the auxiliary core (H1) is connected to when querying the information in the memory core (D) in the auxiliary core. (H1) to be transmitted, which there again immediately if the control relay (R) does not respond is deleted. 7. Circuit arrangement according to claim 6, characterized in that after the information has been transmitted to the auxiliary core (H1), the further process steps are handled with the auxiliary core (H1) and that further auxiliary cores (H2, H3) are assigned to this auxiliary core (H1), in which, if necessary, the information can be transmitted. B. Circuit arrangement according to Claim 6, characterized in that that after the information has been transferred to the auxiliary kernel (H1) before the further processing Process steps the information is transferred back to the memory core (D). 9. Circuit arrangement according to one of the preceding claims, characterized in that that the memory core (D) has an input winding (I) via which the information is to be saved. 10. Circuit arrangement according to one of the preceding claims with a four-digit binary representation for ten magnetization levels, characterized in that an additional marking point (0) is provided in the output device to convert the binary representation into a "2 of 5" code, which is additionally marked, if only one binary digit was marked in the course of the reading process, and that the marking of the marking points for the three smallest binary digits (4, 2, 1) in the course of one and the same reading process is converted into the marking of the marking points of the two largest binary digits (8, 4) will. 11. Circuit arrangement according to one of claims 1 to 9 with a four-digit binary representation for ten magnetization levels, in which the greatest value of the binary number is reduced by one unit, characterized in that for converting the binary representation into a "2 of 5" code in the Output device an additional marking point (0) is provided, which is also marked if only one binary number digit was marked in the course of the reading process, and that the marking of the marking points for the two smallest (2, 1) and the largest binary number (7) in the course one and the same reading process is converted into the marking of the marking points of the two largest binary digits (7, 4). 12. Circuit arrangement according to claim 10 or 11, characterized in that the additional marking point (0) has a with connected to the inputs at the original marking points (8, 4, 2, 1) exclusive mixing gate is marked. 13. Circuit arrangement according to claim 10, 11 or 12, characterized in that the two largest binary digits (8, 4; 7, 4) are marked together with the help of a coincidence gate (K421; K721), its inputs at the three relevant original marking points (4, 2, 1; 7, 2, 1) are connected and at the output of which there is a switching device (K), via the coincidence gate (K421; K721) through the markings in the working position is brought and thereby from the marking points for the two smallest binary digits (2, 1) removes the markings and at the marking points for the two largest Binary digits (8, 4; 7, 4) apply the respective missing mark. Into consideration drawn pamphlets: U.S. Patent Nos. 2,777,098, 2,846,670; journal of Applied Physics, January 1951, pp. 107, 108; -Electronic Engineering, May 1954, Pp. 193, 194; R. K. Richards, "Arithmetic Operations in Digital Computers," D. van Nostrand Comp. Inc., Princeton, New Jersey, Torontb, London, New York, August 1955, Pp. 178, 179.