CS216065B1 - Wiring a circuit to protect ROM area information in ferrite coincidence memory - Google Patents

Abstract

The invention solves the problem of data protection ν'ΉΟΜ area of coincidence ferrite memory, which is formed in such a way that ferrite cores are missing in the places where the "logical zero" information is to be permanently recorded. The essence of the invention lies in the fact that for the ROM area of the ferrite coincidence memory, the signal exciting current pulses in the blocking conductor of the memory is blocked.

Description

The invention relates to a circuitry for protecting information in the ROM region of a ferrite coincidence memory, wherein the difference between logical zero and logical one is formed by the presence or absence of a ferrite core.

One of the characteristic features of contemporary computer technology is the rapid development of small computing resources. For them, the decisive parameter is low price and low operating costs. These factors are influenced, inter alia, by the cost of the necessary peripheral devices, in particular external memory. Thus, it is not desirable to rewrite the operating system of these small computing resources when connected to a network from external mass storage devices, as is the case with external universal computing resources.

The problem is solved in several ways. If it is computational; The device is designed to work under one or a few predetermined systems, all system programs are placed in the ROM area, ie read only memory, in the operating memory. However, if we want the computing device, such as an intelligent terminal, to be able to work under any operating system, it is desirable to use a voltage independent, e.g., ferrite coincidence memory, as the operating memory. It is possible to load system programs therein by means of a cheap and hence a peripheral device, and after disconnecting the computing means from the network, the programs are retained in the memory. In order to load system programs or, for example, to display images when the computing means comprises a display unit which is operated by the computing means by a fixed sequence of instructions when the user programs are not executed, a ROM area is designated in a portion of the operating memory, where programs of the above type are located.

In a ferrite coincidence memory, the ROM region may be formed such that at the point where one type of information is to be permanently recorded, for example, the logic zero, the ferrite core is removed at the intersection of the coordinate conductors, while one is missing at the point. all of the ferrite cores present in this region are magnetized into one state, in our example into the logical one state. where the ferrite cores are present in the pulse on the memory read winding, in places where the core is absent, the pulse is not generated. The reading amplifiers on the reading coils then evaluate the recorded information. Because reading from coincidence memory is destructive, information in the read area is restored in the next loop. This is done at the point where logical one information is to be recorded, ie at the intersection of two coordinate conductors that are passed through a toroidal ferrite core aperture, due to the sum of the two currents in the coordinate conductors, the magnetic field strength causes magnetization of the ferrite core. Where a logic zero is to be recorded, a current is excited in the third, so-called blocking conductor, which passes through the nucleus, the effect of which is subtracted from both coordinate currents and the magnetic field strength generated is not sufficient to magnetize the nucleus.

From the foregoing description, it is apparent that the information in the ROM region of the ferrite memory created by the above method is vulnerable to writing information logical zero de locations where the ferrite cores are present and into which the computer has been connected to the network

216 065 logical information one recorded. For this reason, you must protect this memory area from writing information.

In the prior art, the protection is implemented in such a way that the input impulse of the start memory is reserved in case of writing to the protected area or the input / read signal is modified for the protected area always to read status.

The disadvantage of these solutions in the coincidence ferrite memory is that the memory blocking circuits are in operation when restoring read information in the ROM region of the memory. Their operation is unnecessary in the ROM area, since they block information from being written to places where ferrite cores are not present and therefore cannot be magnetized. Moreover, the operation of these circuits is the most energy intensive with respect to the total power consumption of the coincidence memory, since it is necessary to block all bits in the logical zero state of the information being restored. Another disadvantage is the longer time to calm the faults of the read winding from the blocking currents of the restored information from the previous memory cycle, which is not negligible in the fast reading sequence of information from the ROM area where the read winding is missing due to missing cores. jad.

The above-mentioned drawbacks are overcome by connecting the information protection circuit in the ROM field of the ferrite coincidence memory according to the invention, characterized in that the start input is connected to the read signal generator block, the first output of which is connected to the write signal generator block input and a blocking signal generator block input connected to a first gate input whose second input is connected to a memory address decoder block to which an input address bus is connected, the gate output connected to a third input of a memory pulse exciter block whose second the input is connected to the output of the write signal generator block and the second output of the read signal generator block is connected to the first input of the memory pulse exciter block.

The advantage of the whole circuit is a substantial reduction in the coincidence memory power consumption when reading in

information from the ROM area created as above. At the same time, the ROM area is protected from overwriting the recorded information without the need for additional memory protection circuits. Also, the interference on the memory read winding from the previous information recovery cycle is significantly reduced.

An example of a circuit of information protection circuit in the ROM area of coincidence ferrite memory and functional waveforms are shown in the following figures, wherein Fig. 1 shows an example of a basic circuit of information protection circuit according to the invention. .

The start input 53 of the circuit (not shown) is connected to the input of the read signal generator block 5. The second output 52 of this block is applied to the first input 6l of the memory pulse exciter block 6. The first output 51 of the read signal generator block 5 is connected to the input 4.1 of the write signal generator block 4 and to the input 21 of the blocking signal generator 2. The output 42 of the witch signal generator block 4 is connected to the second input 62 of the memory current pulse block 6. Output 22 of signal generator block 2

The blocking 216 216 is connected to the first gate input 11 χ. An address bus 31 from circuits not specified is connected to block 2 of the memory address decoder. The output 32 of this memory address decoder block 2 is applied to the second input 12 of the gate X, whose output 13 is connected to the third input 63 of the memory pulse exciter block 6.

The operation of the ROM information protection circuit of the ferrite coincidence memory of FIG. 1 is described below. When information outside the ROM area created in the coincidence ferrite memory is read or rewritten as described above, the operation of the memory protection circuit is described below. following. If a start pulse of the memory is applied to the start input 53, a pulse is generated in the write signal generator block 52 on the conductor 52, which is commanded by the memory pulse drivers to excite current pulses for reading information from the coincidence ferrite memory. selected ferrite cores. Upon completion of the pulse at the output signal block 52 of the read signal generator, the information recovery cycle occurs. First, by terminating the pulse on conductor 52, a pulse write on output conductor 42 is energized by means of conductor 51 in signal generator block 6. On the basis of this, current pulses on selected coordinate conductors of opposite polarity are excited in block 6 of current pulse drivers. pulse duration on conductor 52. In the event of recovering or writing logic zero information, an output pulse 13 of gate X is energized to provide a coincidence ferrite memory blocking conductor of opposite polarity pulse along with both coordinate currents in selected conductors creates in the selected cores a magnetic field strength that does not cause magnetization of these cores to the logical one state. In the case of recovered or written information, a logical one pulse on the wire 12, and based on it, does not generate a pulse in the blocking wire, and logical one information is recorded in the core. So far, the activity is the same as with conventional coincidence ferrite memory. The protection in the ROM area based on the patent is performed such that the generation of the blocking signal on the conductor 13 is blocked all the time when the ROM area is decoded from the address bus 31 of the memory address decoder block 3 by suppressing all pulses on the conductor 13 that in the ROM area, the logical one itself is always refreshed or written to plowed cores of memory. Because ferrite cores are missing in places where a fixed program has logic zeros missing, they will not be undesirably magnetized to a logic one state. In addition, by blocking the possibility of current pulses in the blocking winding, the logical jedija information in the places where the cores are located is automatically protected against unwanted recovery or rewriting of the information to the logical zero state.

FIG. 2 shows the functional diagrams. Waveform 310 corresponds to signals on bus 31. Waveform 530 on wire 52, Waveform 520 on wire 52. Waveform 420 on wire 42. Fully marked waveform 130 corresponds to signal on wire 13 when the memory is operating outside the ROM area, indicated by broken lines in dashed lines. signal in the ROM area.

Claims (1)

SUBJECT OF THE INVENTION A circuit for protecting information in the ROM region of a ferrite coincidence memory, characterized in that the start input (53) is connected to the read signal generator block (5), the first output (51) of which is connected to the input (41) of the block (4). a write signal generator and at the same time to an input (21) of the blocking signal generator (2), the output (22) of which is connected to the first input (11) of the gate (1), the second input (12) of which is connected to the output (32) (3) a memory address decoder to which the input address bus (31) is connected, the output (13) of the gate (1) being connected to a third input (63) of the memory pulse exciter block (6), the second input (62) it is connected to the output (42) of the write signal generator block (4), while the second output (52) of the read signal generator block (5) is connected to the first input (6l) of the memory pulse exciter block (6).