SU446881A1 - Information processing device - Google Patents

Description

The invention relates to automation and computer technology and, in particular, can be used in radioisotope thickness gauges of two-layer coatings using discrete information processing methods, or in other areas of non-electrical measurement, where measurements are made by processing discrete information of the two pulsed streams, if one of them has a functional dependence on only one parameter, and the other has a functional dependence on Their measured parameters: n, A + f (x); (1) n, (x) - (y); A device for information processing is known, which includes a measurement time counter, a control unit, nonlinear average frequency meters, a control trigger, reversible counter, logic circuits “AND,“ OR, additional pulse counter. However, none of the known devices allows obtaining a result if the input pulses of one channel have a functional dependence on both measured parameters. To solve the problem with the help of known devices, it is necessary to use a two-channel meter of the average frequency of pulses and the classic blocks of electronic computers or to calculate the result manually. The disadvantage of this solution is a large hardware complexity, which, in turn, reduces the reliability of operation. The aim of the invention is to expand the scope and increase the reliability of a two-channel information processing device, in which the result is output in digital form separately for each measured parameter. The goal is achieved by the fact that in the device the input of the measurement time counter is connected to the first input of the device, the second input of the first "I" circuit, and the output to the input of the control unit, the first output of which is connected to the first inputs of the second, third "And" circuit and the first reversing input counter, and the output of the second circuit "And connected to the input of the first nonlinear average frequency meter, the output of which through the second nonlinear average frequency meter connected to the first input of an additional pulse counter, the output of which connected to the input of the third nonlinear meter, and the output of the third AND circuit is connected to the first input of the OR circuit, the output of which is connected to the second input of the reversible counter, the output of which is connected to the first input of the first AND circuit via the fourth And circuit, and the output which is connected to the second input of the additional pulse counter and the second input of the OR circuit, the second output of the control unit is connected to the third input of the first AND circuit, the third input of the reversible counter and the second input of the fourth AND circuit, and the second The second and third circuits are connected to the second and third inputs of the device, respectively.

The drawing shows a block diagram of the proposed information processing device, which shows the counter 1 time, no measurement; control unit 2; logic circuit "And 3; the first nonlinear midrange frequency meter 4, which includes a control trigger 5, a pulse counter 6 with a variable conversion factor, a main pulse counter 7, a decoder 8, a memory 9, an AND 10 circuit; second and third nonlinear mid-frequency meters 1I and 12, additional pulse counter 13, first logic circuit "And 14, reversible pulse counter 15, fourth logic circuit" And 16, control trigger 17, third logical circuit "And 18, logic circuit" OR 19, entrances 20, 21, 22.

The device works as follows.

In the initial state, before the measurement is started, the main pulse counter 7 of the first nonlinear meter 4 of the middle frequency

set to -, where / C - nK

The initial conversion factor of the pulse counter 6 with a variable conversion factor, the reversible pulse counter 15 is set to minus B, and all other pulse counters and the memory device are set to the zero state via a reset circuit (the reset circuit is not shown conventionally in the drawing). The input 20 is supplied with pulses that specify the measurement time (for example, from a crystal oscillator). The corresponding measured pulse flows are fed to inputs 21 and 22.

At the beginning of the measurement cycle, the input pulses in the first channel through the AND 3 circuit are fed to pulse counter 6 with a variable conversion factor, where the pulses are divided by the initial conversion factor / C and fed to the main counter of pulses 7, where the background value is subtracted, after which the counter 7 of the first nonlinear meter 4 of the average frequency of the pulses is in the zero state and the control trigger 5 is thrown, which through the memory 9 changes the conversion factor of the counter 6 to the corresponding connecting the first nonlinear meter AND the average frequency of the pulses parallel to the main pulse counter 7 of the first nonlinear meter

average frequency of impulses. When in the triggers of the counter 7 the number corresponding to the first inflection point of the approximating direct is written down through the decipher 8 and the storage device 9, the conversion factor of the pulse counter 6 will change with a variable conversion factor, etc. Thus, a linear approximation of the function occurs:

0x F (ti, -A). (3)

The second nonlinear average frequency meter in a similar way produces a linear-piecewise approximation of the function

5 (f (x) and at the end of the measurement cycle, the result will be recorded in the main pulse generator 7 of the first nonlinear average pulse frequency meter; and in the main pulse counter of the second nonlinear meter

0 average frequency will be recorded the result of f (x).

At the same time, the input pulses in the second measurement channel through the circuit "AND 18, the circuit" OR 19 are fed to a reversible counter

5 pulses 15, where first the background value of the pulses is subtracted - B, and then the count of the pulses during the measurement time. At the end of the measurement cycle, the control unit 2 locks the AND 3 and 18 circuits, switches the reversible pulse counter 15 to subtracting the pulses and opens the AND 16 circuit, while the pulses from the input 20 through the AND 14 circuit are fed to an additional impulse counter 13, where TC to the coefficient corresponding to the measured value of f (-), and fed to the third nonlinear meter 12 of the average frequency of the pulses; at the same time, the pulses from the output of the circuit "AND 14 through the circuit" OR 19 are fed to the input of the reverse

0 pulse counter 15, where the number of the number recorded during the measurement cycle is subtracted. Thus, after the reversible pulse counter 15 returns to the zero state via the AND 16 circuit, control trigger 17 is switched, which stops the pulses through the AND 14 circuit and the additional pulse counter 13 to the input of the third nonlinear meter 12 of the average frequency pulses and in his

0 the main pulse counter 7 will be recorded the result of the second measured value:

Mr. La -V ...

NG77G - (4)

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Subject invention

Information processing device

measuring time keeping block

control, nonlinear meters. average

frequency, trigger control, reversing

counter, logic circuits "AND," OR, up to an additional pulse counter, characterized in that, in order to expand the scope, the input of the measurement time counter is connected to the first input of the device, the second input of the first "AND circuit, and the output to the input of the block control, the first output of which is connected to the first inputs of the second, third And circuits and the first input of a reversible counter, and the output of the second And circuit is connected to the input of the first nonlinear average frequency meter, the output of which is through the second nonlinear average frequency meter s are connected to the first input of an additional pulse counter, the output of which is connected to the input of the third nonlinear average frequency meter, and the output of the third

The AND circuit is connected to the first input of the OR circuit, the output of which is connected to the second input of a reversible counter, the output of which through the fourth AND circuit, the control trigger is connected to the first input of the first AND circuit, the output of which is connected to the second input of an additional pulse counter and the second the input of the OR circuit, the second output of the control unit is connected to the third input of the first AND circuit, the third input of the reversible counter and the second input of the fourth AND circuit, and the second inputs of the second and third AND circuit are connected to the second and third inputs of the device Respectively, respectively.