SU1280449A2 - Programmer for writing information in semiconductor memory elements - Google Patents

Abstract

The invention relates to computing technology, in particular, to information recording devices by burning the jumpers in semiconductor memory elements used in ROM. The invention is an improvement on the auth. No. 809355. The purpose of the invention is to increase the reliability of the programmer. The goal is achieved by introducing the control driver of the impulses and the AND element, which makes it possible to achieve the adaptation of the programming pulse duration to the individual characteristics of the burned-through jumper. This makes it possible to shorten the programming time and exclude the possibility of the matrix overheating with S. 4 il. (P

Description

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Claims (1)

CX) The invention relates to computing, in particular to information recording devices by burning jumpers in semiconductor memory elements used in ROM, and is complementary to the main autom.w. No. 809355. The purpose of the invention is to increase the reliability of the programmer. FIG. 1 shows a block diagram of the programmer; in fig. 2 is a block diagram of an automatic change of the duration of a write cycle; FIG. 3 timing diagrams (a - for the programming mode of defect-free memory elements, b - for the programming mode of defective memory elements); in fig. 4 is a block diagram of the control and control unit. The programmer (Fig. 1) contains a memory block 1, a data input bus 2, a data input / output block 3, a connector 4 for connecting the programmer output buses to the outputs of a programmable memory matrix, an address counter 5, the control and monitoring unit 6, the first 7, the second 8 and third 9 output buses of the programmer, respectively, the unit 10 automatically changing the duration of the recording cycle, the pulse width generator 11, the first 12 and second 13 output buses of the unit 10 automatically changing the recording cycle duration, pulse width meter 14, form globalizer 15 pause duration, current sensor 16, amplifier 17, direct 18 and inverse 19 outputs of the amplifier, first 20 and second 21 elements AND, generator 22 clock pulses, reversible counter 23 input 24 direct counter of the reversible counter, third element AND 25 , the frequency divider 26, the reverse counting input 27 of the reversing counter 23, the decoder 28 zero state of the counter 23, the inverter output 29 of the decoder, the driver 30 of control pulses, the fourth element And 31, its output 32, the output 33 of the driver 30, the bus C- data source synchronization with programs torus. Control and control unit 6 (Fig. 4) contains a pulse generator 34, a set of buttons 35 for manually controlling the programmer, the first trigger 36 for controlling the process of recording information in memory block 1, 1 9 fifth element AND 37, first element OR 38 driver 39 data writing pulses in memory block 1, a reset pulse shaper 40 for data input / output unit 3, a data read pulse shaper 41 from memory block 1, a second element OR 42, a second trigger 43 for controlling the programming process, a sixth And 44 element, third trigger 45 signaling and a general reset (signaling that the ROM matrix contains defective memory elements), the driver 46 of the impulse entering information from the memory 1 to the block 3 input - output data, a set of transistor switches 47, providing the formation of voltage pulses of the required amplitude ( accordance with the technical characteristics of the programmable matrix ROM). The programmer works as follows. Let us first consider the case of programming defect-free (fully functional) matrices of semiconductor memory elements (ROM matrix). A slot of the ROM to be programmed is plugged into slot 4. Then, when the KN1 button is pressed in the monitoring and control unit 6, the address meter is reset to the zero state, and the trigger 36 is set to one state and enables the pulses from the generator 34 to pass through the element 37, which through the element 38 is fed to the counting input of the counter 5. Under the action of each pulse from the output of the AND 37 element, the shaper 39 generates a pulse, under the action of which the data representing the program (ROM codes) is written to block 1. Data on the bus 2 comes from an external device. For synchronous operation of the programmer with this external device, a bi-directional sync bus is provided. After recording the program in memory block 1, trigger 36 is set to the zero state (using the KH2 button), and counter 5 is reset to its initial state, and the starting address of memory block 1 is selected. The start of programming is determined by pressing the button of the CLZ in block 6. 31 The trigger 45 is set to the zero state, and the trigger 43 - to the single opening element AND 44. It may be with that by this time the state of the counter 23 will not be zero, but arbitrary . As a result, a signal 1 is generated at the inverse output 29 of the decoder 28, which opens element AND 25. At the inverse output 19 of amplifier 17, signal 1 is also generated, therefore the pulses from the clock generator 22 through the open element 25 are fed to frequency divider 26 and reduced by a factor of K to input 27 of counter 23 (K is the division factor of frequency divider 26). Under the action of each pulse generated by frequency generator 26, the contents of counter 23 decrease by one until its content is equal to O . In this moment In time, the logic levels at the outputs of the decoder 28 are reversed, as a result of which the element AND 25 closes, and on the bus 13 a Start signal arrives simultaneously in block 6 (at the input of element AND 44), at the input of the imaging unit 30 and element And 31 The appearance of the Start signal corresponds to the start of burning the jumper of the selected semiconductor memory element, i.e. This signal determines the start of programming. Under the action of this signal, Shaper 30 forms at output: 33 a pulse, the duration of which is even and determined for a particular JHoro type of ROM matrix, and this must be slightly longer than the maximum required burning time of defect-free elements of the .e.YgS memory ep. man sn gpah Simultaneously with the Start signal, the block 6 generates a signal providing the programming mode of the memory element and arriving at connector 4. The Bus 13 start signal through the open element I 44 enters the pulse shapers 41 and 46 The shaper 41 generates a data read signal from the first selected cell of the memory block 1 and the shaper 46 is a pulse, under the action of which data is entered into the register of the block 3 9 which then goes to the inputs of the bit transistor 47 keys of the block 6. To the inputs of the other keys programming solutions receive pulses from the output of the AND 44 element and from the output of the driver 46. The voltage impulses of the corresponding polarity and amplitude come from the outputs of the keys via bus 8 to connector 4. The main programming pulse via bus 9 goes to connector 4, while the sensor 16 current begins to flow non-zero programming current of the selected jumper. The current sensor 16 generates a signal when current flows, which triggers the second element 21 and 21 and opens the second element 21 and pulses from the generator 22 to the input 24 of the forward counting counter 23. The forward counting process continues until the counter 23 until the programming current flows through sensor 16. When the selected jumper is destroyed, the current in the bus 9 is stopped, the voltage drop on the sensor 16 is reset to zero, and the amplifier 17 returns to its original state. The input of the first element And 20 receives a signal 1 from the inverse 19 output of the amplifier 17. The other input of the first element And 20 receives a signal 1 from the transistor of the current sensor 16 connected to block 6, since the voltage of the main programming pulse continues to act despite the current termination in the bus 9. As a result, the element I 20 opens and on the bus 12 of the block 10 a Stop signal is generated, which enters the input of the driver 40 of the block 6. With this signal, the last interrupt is the programming mode of the selected jumper. Thus, the termination of the programming pulse and the transition to the pause occurs immediately after the resolution of the selected jumper. In this case, the duration of the programming pulse has a random value T ", determined by the characteristics of a specific jumper (memory element), but not exceeding the value, i.e. G ,,,.; jp. Since Tj o and, the element And 31, (Fig. 3a) does not generate a general reset signal, which indicates that the programmable memory element has no defects, and the programmer can continue to work. At the moment the current stops in bus 9, a signal O is formed at the main output 1 of amplifier 17, and element 21 is closed. In this case, the signal from the generator 22 to the input 24 of the direct counting of the counter 23 is stopped, and a number proportional to the duration of the completed programming pulse is recorded in it. The termination of the pulse and the installation of the amplifier 17 to the initial state (zero) leads to the formation of 19 M at its inverse output, the third element I 25 opening, since the state of the counter 23 is nonzero and 1 is also formed at the output 29 of the decoder 28. As a result, the pulses from the generator 22 through the frequency divider 26 are fed to the inlet 27 of the counting counter 23. Because the frequency of these pulses is K times lower than the generator frequency of 22 clocks, the time required to clear the counter 23 is K times what time is it and complements, t, e, K pause time is longer programming pulse that is necessary for thermal Compliance programming mode. Since a pause in K times longer than a pulse for any duration of it, a constant value of the duty cycle of the programming pulses, i.e. The constant value of the average power is dissipated on the memory element of the ROM matrix in the programming mode. When the zero state of the counter 23 is reached, the output signals of the decoder 28 are inverted, as a result of which the element AND 25 is locked, and on the bus 13 of block 10 a Start signal appears, which enters the block. 6. This pause ends and a transition is made to another address programmable matrix. To do this, during a pause, block 6 generates a signal to the address counter and selects the next address of memory block 1 and the matrix of the programmable ROM. Further, the operation of the programmer is repeated cyclically. 12 96 Consider now the case of programming the ROM matrix containing defective memory elements. A very common defect is non-programmable (non-flammable) jumpers, and this defect can only be discovered by programming, with the programming ratio specified in the technical characteristics of a specific series of ROM matrices, always less than one and usually 0.5-0.8. In the proposed device, the programming current pulse starts at the moment of the appearance of the signal. Start on the bus; 13. At this point, the generation of a pulse of duration t begins. rover 30 (Fig. 3). Since the jumper is not burned, then T, n max and, therefore, on o. Therefore, at the output of the fourth element And 31, a reset signal is generated on bus 32 arriving at block 6. This signal indicates that the programmable ROM matrix is defective, its further programming is impractical and must be disconnected from slot 4. By the action of this signal on bus 32 the trigger 43 of block 6 is set to the zero state, which indicates the end of the programming process, and the trigger 45 is set to one, which signals that this cell of the matrix has a defect, i.e. matrix is defective. Invention programmer for recording information. into semiconductor memory elements according to auth.st. No. 809355, characterized in that, in order to increase the reliability of the programmer, it comprises a control pulse driver and an element, the first input of which is connected to the output of the control pulse generator, an input of the control pulse generator and the second input of the element And are connected to the second output of the unit automatically changing the duration of the recording cycle, and the output of the AND element is connected to the fourth input of the control and monitoring unit. tpi / e.4