SU898411A1 - Multi-channel device for input of data into digital computer - Google Patents

Description

The invention relates to computer technology and can be used in process control systems, in particular in the textile industry, when there are a large number of objects to be controlled and it is required to provide automatic collection and processing of information.

A device is known for interfacing a computer with on-position pulse sensors, comprising a pulse shaping unit, a group coding unit, a matching unit, an OR circuit, and an output register. This device implements a method of probabilistic-time separation of messages in a common communication channel, a method of unorganized transmission of signals from multiple sources to the receiver through one common communication channel. With its help, it is possible with high accuracy (achieved value of 10 ^-5 s) 'to measure the response time of discrete sensors [1].

A disadvantage of the known device limiting its functionality is that it does not allow analog sensors to be connected to the input of a computer.

A device is also known based on the method of time-probability separation of messages in a common communication channel. The device includes 'conversion start nodes, reference voltage generators, null organs, a time pulse generator, a time pulse counter, a switch, a group of elements I. The device + input for each mating sensor is connected to the input of the' Launch conversion node and the first input of the main zero organ. The output of each conversion start node is connected to the 'first for the conjugated sensor input of the shaper group and the input of the reference voltage generator. The second input of the main null organ is + connected to the output of the reference voltage generator, and the output is connected to the second input of the shaper group for the sensor. The first and second outputs for each mating sensor of the shaper group are connected to the corresponding ₅ inputs of the encoder. The input of the matching node is connected to the output of the encoder, and the output is connected to the input of the OR element and the first input of the output register. A first input switch connected to the house ₁₀ The yields of the OR gate, the second input - with the output of the pulse generator of time, the first output - with the time pulse counter, and the second output - to the first input group of AND gates ₁₅ and per- vym output device. The second input of the group of elements And is connected to the output. house of the time pulse counter, and the output with the second input of the output register, the control input of which is connected to the control input of the device, and the output with the second output of the device [21.

A disadvantage of the device is comparatively low reliability pe- ₂₅ redavaemoy information due to the change with time of characteristics used by the reference voltage generator, which reduces the reliability of the device. Verification and adjustment of a large group of reference voltage generators is associated with great labor costs, and it is not possible to achieve high stability over time of steepness, in particular, sawtooth generators. ³⁵

The purpose of the invention is to increase reliability.

This goal is achieved by the fact that in a multi-channel device for entering data into a digital computer 40, containing a pulse shaper, an OR element, a switch, a time pulse generator, a counter, an I block, an register, an encoder, and a single-shot in each channel, a reference voltage generator, a nullorgan and a pulse shape shaper, the input of the channel single vibrator being one of the inputs of the group of information inputs of the device and connected to the first input of the channel zero organ, the output of the single channel vibrator the channel is connected to the first input of the channel pulse shaper and through the channel reference voltage generator g- ₅₅ to the second input of the channel zero-organ, the channel zero output is connected to the second input of the channel pulse shaper, the first and second outputs of the pulse form connected to the corresponding inputs of the encoder, the group of outputs of which through a pulse former is connected to the first group of information inputs of the register, the outputs of the pulse former through OR elements are connected to the first input ohm of the switch, the second input and the first output of which are connected respectively to the output of the time pulse generator, and with the counting input of the counter, the outputs of which are connected to the group of information inputs of the block of elements AND, the second output of the switch is connected to the first output of the device and to the control input of the block of elements AND the outputs of which are connected to the second group of register information inputs, the output and control input of the register are respectively the second output and control input of the device, the reference voltage, and in each channel - an additional zero-organ and power amplifier, and the output of the reference voltage source is connected to the inputs of the channel power amplifier, the output of the channel power amplifier and the output of the channel voltage generator through the additional zero-channel organ are connected to the third input a pulse shaper of the channel, the third output of which is connected to the corresponding input of the encoder.

The drawing shows a structural diagram of the device.

A device for inputting data into a digital computer contains channels 1, 2, each of which is made in the form of null organs 3 and 4, a power amplifier 5, a pulse shaper 6, a reference voltage generator 7, a one-shot 8. In addition, the device contains an OR element 9, register 10, time pulse generator ^ / switch 12, counter 13, block 14 And, source of voltage reference 15, encoder 16, pulse shaper 17, information inputs 18 th 19, control input 20, outputs 21, 22.

The device operates as follows.

The voltage from the outputs of the mating 'analog sensors is constantly applied through the inputs 18 and 19 of the device to the inputs of the corresponding single-vibrator 8 and the first inputs of the main zero5 8984 organs 3 · The single-vibrator 8 gives a command pulse to the input of the reference voltage generator 7 and the first input of the shaper 6 for this mating sensor The generator of reference voltage 5'7 is turned on and generates a voltage that varies in time according to a given law and is supplied to the second input of the main zero-organ 3. In the former 6, the input is * 0 w th impulse is required for a normal operation of the short duration of the device. Next, the generated pulse is fed to the corresponding input of the encoder 16, in which: a rum based on it forms a message code about the beginning of the voltage conversion of the corresponding sensor. From the output of the encoder 16 via the communication line, the message code is supplied to the pulse shaper 17, in which the bit pulses of the message code are converted to the form required for further operation of the device. Next, the message code arrives at the input of the OR element 9 and through the first group of inputs — to the part of the bit triggers of register 10, which are used to memorize. In element OR 9, based on the pulses of the incoming binary code, a single pulse is generated that is output to the first input of switch 12. At the second input of this switch, rectangular pulses from the output of the time pulse generator 11 are received in a continuous series. If in switch 12 there is no pulse from the output of OR 9 , the pulses of the pulse generator of time 11 pass to the input of the counter 13 "which records the time P ^{and the} bots of the device. When the pulse passes through the switch 12 from the output of the OR element 9, the next pulse of the time pulse generator 11 is delayed for half a period 11. The transients in the counter 13 end, after which the pulse of the OR element 9 appears at the second output of the switch 12 and goes to the 'first input block 14 VI elements the second inputs of block 14 ^th element and the head unit 13 outputs counter triggers · Therefore, when the pulse arrives at the first input of the unit 14 and carried elements rewriting the contents of the counter 13 through ^55, through the second group of inputs of register 10 into the second part of its triggers. The pulse of the OR element 9 from the output of the switch 12 is supplied to the first output of the device 21, being a signal for the _z computer about the receipt of the next message from the mating sensors. On its basis, the computer gives a command to the control input 20 of the device, which overwrites the contents of the register 10 in the memory of the computer. So, the address of the sensor on which the analog-discrete conversion is started ή the start time of the conversion · ¹ conversion is recorded in the computer.

At the moment of convergence of the converted voltage and the voltage at the output of the reference voltage generator 7 on. the inputs of the main * null-organ 3, a single pulse appears at its output, arriving at the second input of the shaper 6 for this mating sensor. After bringing it to the desired shape, it goes from the corresponding output to its own input of the encoder 16, in which a message code about the end of the conversion at the mating sensor in question. As a result of further operation of the device described earlier, the address of the sensor at which the conversion ended and the time the conversion ended are recorded in the memory of the mating computer.

At the moment of coincidence of the output voltage of the generator 7 and the reference voltage at the amplifier output 5> is input to the additional zero-body 4 is formed at its output a single pulse supplied to the third for the matched sensor input of 6. After ⁴ x pref it to Denia in the required form, it comes from ^the corresponding output of the shaper to its own input of the encoder 16, in which a message code is generated about the end of verification of the characteristics of the generator of the reference voltage of the sensor in question. 3 as a result of the further operation of the device described earlier, the address of the sensor at which verification was completed and the time of completion of verification are recorded in the memory of the mating computer.

The amplifiers 5 through the communication line is supplied with a constant reference voltage from a source of reference (constant reference) voltage 15, which is, for example, a normal element. Amplifiers 5, which are dressings ^t toritelyami reference voltage have a very high input impedance DC · far superior resistance trunks. At the same time, they 5 have a very small input resistance to alternating current, and therefore they eliminate the interference voltage appearing at the output of the connecting lines. As amplifiers 5, in particular, emitter (cathode) repeaters can be selected, in parallel with the input of which capacitors of higher ratings or more complex filters are included. Additional null organs 4 are completely similar to the main null organs J. The remaining elements of the device repeat the design of similar elements of the known device.

In the known device, the calculation of the transmitted parameter U _x , controlled by the mating sensor, is carried out according to the formula

U * = K (t _k -t _H ), (1) in which, due to the instability of 25 characteristics of the generator of the reference voltage 7, the value of the conversion coefficient K is known with a significant error. In the invention, 'the value of the coefficient K is refined by Sv at each measurement ^to -vnr' ⁽² > and the calculation of the value of the parameter controlled by the mating sensor is carried out according to the formula

those. significantly more accurate (here (Ts is the voltage of the constant-voltage source - “voltage 15”), which improves the reliability of the device.

Claims (2)

The invention relates to computing technology and can be used in an automated process control system, in particular in the textile industry, when there are a large number of objects to be monitored and it is required to ensure automatic collection and processing of information. A device for interfacing a computer with / auxiliary pulsed sensors is known, comprising a pulse shaping unit, a group coding unit, a matching unit, an OR circuit, and an output register. This device implements a method of probability-time separation of messages in a common communication channel, a method of unorganized transmission of signals from multiple sources to a receiver via one common communication channel. With its help, it is possible to measure the response time of discrete sensors with high accuracy (10 s value is reached). A disadvantage of the known device that limits its functionality is that it does not allow analog sensors to be connected to the computer input. It is also known a device based on a method for the probabilistic-temporal separation of messages in an OC channel. The device includes transformation start nodes, reference voltage generators, zero-organs, time pulse generator, counter; time pulses, switch, element group I. A device input for each interfaced sensor is connected to the input of the conversion start node and the first input of the base zero -organ. The output of each conversion triggering node is connected to the first for the interfaced sensor input of the group of drivers and the input of the reference voltage generator. The second input of the main null organ is connected to the output of the reference 3 voltage generator, and the output is connected to the second input of the shaper group for the sensor. The first, first and second outputs for each co-current sensor of the group of drivers are connected to the corresponding inputs of the encoder. The input of the matching node is connected to the output of the encoder, and the output is connected to the input of the OR element and the first input of the output register. The first input of the switch is connected to the output of the OR element, the second input is connected to the output of the time pulse generator, the first output is connected to a counter of time pulses, and the second output is connected to the first input of the AND group and the first output of the device. The second input group of elements And is connected to the output. home of the pulse counter, and the output with the second input of the output register, the control input of which is connected to the control input of the device, and the output with the second output of device 2. The disadvantage of the device is the relatively low reliability of the transmitted information due to the change in time characteristics use of reference voltage generators, which reduces the reliability of the device. Verification and adjustment of a large group of reference voltage generators is associated with large labor costs, and it is not possible to achieve high stability in time-steepness, in particular, sawtooth voltage generators. The purpose of the invention is to increase reliability. The goal is achieved by the fact that a multichannel device for inputting data into a digital computer containing a pulse shaper, an OR element, a switch, a time pulse generator, an AND block counter, a register, an encoder, and in each channel an odovibrator, a reference voltage generator, a null-pulse and a pulse-shaper, with the input of the channel single-oscillator being one of the inputs of the group of information inputs of the device and connected to the first input of the zero-channel organ, the output of the single-oscillator of the channel inn with the first input of the channel pulse shape generator and through the channel reference voltage generator with the second input of the channel zero-channel, the output of the channel zero-channel is connected to the second input of the channel pulse name generator and the channel pulse shaper first and second outputs are connected the inputs of the encoder, the group of outputs of which through the pulse shaper is connected to the first group of information inputs of the register, the outputs of the pulse shaper through the elements OR are connected to the first input to mmutator, the second input, and the first output of which are connected respectively to the output of the time pulse generator, and to the counter input of the counter, the outputs of which are connected to the group of information inputs of the I block, the second output of the switch is connected to the first output of the device and to the control input of the block of VI elements , the outputs of which are connected to the second group of information inputs of the register, the output and the control input of the register are respectively the second output and the control input of the device, the reference source is entered each channel contains an additional null organ and a power amplifier, the output of the voltage source being connected to the inputs of the channel power amplifier, the output of the channel power amplifier and the generator output of this channel voltage of the channel are connected via an additional zero channel organ. with the third input of the pulse wave former, the third gate of which is connected to the corresponding input of the encoder. The drawing shows a block diagram of the device. The device for data input. -In the digital computer contains channels 1, 2, each of which is made in the form of zero-organs 3 and 4, power amplifier 5, pulse shape generator 6, generator of reference voltage 7 of one-vibrator 8. In addition, the device contains OR 9, register tO, time pulse generator 11, switch 12, counter 13, AND unit 1, reference voltage source 15J encoder 16, pulse driver 17, information inputs 18 and 19, control input 20, outputs 21, 22. The device works as follows. The voltage from the outputs of mated analog sensors is continuously applied through the inputs 18 and 19 of the device to the inputs of the corresponding single vibrators 8 and the first inputs of the main zero organs 3. The single vibrator 8 outputs a command pulse to the input of the reference voltage generator 7 and the first for this mate sensor input of the driver 6. The generator of the reference voltage 7 turns on and generates a time varying voltage according to a given law applied to the second input of the main zero body 3. In the driver 6, the the impulse results in a short duration required for normal operation of the device. Next, the generated pulse arrives at the corresponding input of the encoder 16, in which the ipohoM on its basis forms the code indicating the start of the pre-voltage of the corresponding sensor. From the output of the encoder 16, the message code is fed to the pulse driver t7 via a communication line. in which the bit pulses of the message code lead to the form required for the further device. The message code then goes to the input of the element OR 9 and 4 & the first group of inputs is cut from a part of register triggers of register 10, which are memorized. 8 element OR 9 based on the pulses of the incoming parallel binary code, a single pulse is generated that is output to the first input of the switch 12. The second input of this switch is received in a continuous series of rectangular and polys from the output of the time pulse generator 11. If the switch 12 has a pulse from the output of the element OR 9 is absent, the pulses of the generator of the pulses of time 11 are passed to the input of the counter 13, which fixes the operating time of the device. When a pulse from the output of the element OR 9 by the switch 12 is passed through half a switch through the switch 12, the next pulse of the time pulse generator 11 is delayed. The transients in the counter 13 end, after which the pulse of the element OR 9 appears at the second output of the switch 12 and enters the first input of the block of elements I. At the second inputs of the block of elements I, the unit outputs of the triggers of the counter 13 are entered. Therefore, when a pulse arrives at the first input of the block 1 of the elements I, the contents of the counter are rewritten for 13 hours Res second group input register 10 to the second part of its triggers. The impulse of the element OR 9 from the output of the switch 12 is also fed to the first output of the device 21, which is a signal to the computer about the receipt of the next message from the associated sensors. On its basis, the computer issues a command to the control input 20 of the device, which is used to overwrite the contents of the register 10 in the memory of the computer. Thus, the address of the sensor at which the analog-to-discrete conversion is started, and the time t | j of the start of the transformation, is written to the computer. At the moment of convergence of the voltage being converted and the voltage at the output of the generator of the reference voltage 7 on. Inputs of the main body 3, a single pulse appears at its output. It arrives at the second input for the given mating sensor. After bringing it to the required form, it comes from the corresponding output to the own input of the coder t6, in which the code messages about the end of the conversion on the sensor in question. As a result of the further operation of the device described earlier, the address of the sensor at which the conversion ended, and the end time of the conversion, are recorded in the memory of the associated computer. At the time of coincidence of the voltage at the output of the reference voltage generator Y and at the output of amplifier 5 supplied to the inputs of an additional null organ i, a single impulse is generated at its output, which is supplied to the third input 6 of this sensor for this interfaced sensor; to the required form, it from the corresponding output of the driver 6 enters the own input of the encoder 16, in which the code is generated reporting the end of the calibration of the characteristics of the generator of the reference voltage 7 of the sensor in question. 3, as a result of the further operation of the device described earlier, the address of the sensor at which the verification has ended and the time of the end of the calibration are recorded in the memory of the interfaced computer. The amplifiers 5 are supplied with a constant reference voltage from the source (constant reference voltage 15, which is, for example, a normal element. Amplifiers 5 which are repeaters of the reference voltage have a very large DC input resistance, which is significantly superior to the resistance of the connecting lines. At the same time, they have very low AC input resistance, and therefore they eliminate the voltage disturbances that occur at the output of the connecting lines. As amplifiers 5, emitter (cathode) repeaters, in particular, can be selected, in parallel to the input of which capacitances of larger values or more complex filters are included. (B) the complementary zero-organs of C are completely analogous to the basic null-bodies 3. The remaining elements of the device repeat the construction of similar elements of the known device. In the known device, the calculation of the transmitted parameter 0, controlled by the associated sensor, is carried out according to the formula and, K (), (1) in which, due to the instability of the characteristics of the generator of the reference voltage 7, the value of the conversion coefficient K is known with considerable error. In the invention, the value of the coefficient K is refined with each measurement. (2) and the calculation of the value of the parameter controlled by the conjugated sensor is carried out according to the formula tH-t. much more precisely (here, Uj, the voltage of the constant voltage source 15), which makes it possible to increase the reliability of the device. Claims of the Invention Multichannel device for data input into a digital computer containing a pulse shaper, elekt-OR, switch, time pulse generator, speed generator, AND components, register, encoder, and in each channel a single-oscillator, reference voltage generator, zero organ, and a pulse shape generator, the input of the one-vibrator channel 8 11 being one of the inputs of the group of information inputs of the device and connected to the first input of the channel zero-organ, the output of the single-channel channel is connected to the first the channel pulse driver and, through the reference channel voltage generator, with the second input of the channel zero-channel, the output of the channel zero-channel is connected to the second input of the channel pulse form generator, the first and second outputs of the channel pulse generator are connected to the corresponding encoder inputs, group of outputs which through the pulse shaper connected to the first group of information inputs of the register, the outputs of the pulse shaper through the OR element connected to the first input of the switch, the second The first input and the first output of which are connected respectively to the output of the time pulse generator and to the counter input of the counter, the outputs of which are connected to a group of information inputs of the block of elements I, the second b. The switch's input is connected to the first output of the device and The outputs of which are connected to the second group of information inputs of the register, the output and the control input of the register are, respectively, the second output and the control input of the device, so that, in order to increase the It contains a reference voltage source, and each channel contains an additional zero-organ and power amplifier, the output of the reference voltage source being connected to the inputs of the channel power amplifiers, the output of the channel power amplifier and the output of the reference voltage generator through an additional zero-organ the channel is connected to the third input of the forker forcing {pulses of the channel, the third output of which is connected to the corresponding input of the encoder. Sources of information taken into account during the examination 1. Authors svid USSR USSR No. 37157, cl. G About F 3 / OA, 1970. 2. USSR author's certificate for application No. 266637VlB-2i, cl. G About F 3/0, 10.0. 79 (prototype).