SU834560A1 - Average pulse frequency digital non-linear meter - Google Patents

Description

(54) DIGITAL NONLINEAR MEASURING MEDIUM FREQUENCY PULSES

Claims (2)

The invention is fire based on automation and computer technology, and, in particular, is intended for use in radioisotope power engineering, for example, in radioisotope density metering and thickness gauges, where measurements are performed by processing discrete information and the average frequency of the input pulses has an exponential dependence on the measured parameter. Devices are known that contain input - code counters, desh atsche and an OR circuit in which the output of an input counter with a variable conversion factor is connected to the input of the output counter, to the outputs of which bits. A decoder is connected, the outputs of which correspond to the same conversion factors are connected via the OR circuit to the inputs of the conversion control of the input counter D. The disadvantage of the devices is complicated regrading from one logarithmic relationship to another, since it is necessary to set billing points and angular coefficients of each approximating direct. The closest in technical essence to the proposed invention is a device containing a stable frequency generator, circuits AND, a series-connected adder, a measurement time counter, a control trigger, as well as a stable frequency EL generator and a measuring counter. However, the device has insufficient, wide measuring range. The purpose of the invention is to expand the measurement range. The goal is achieved by the fact that in a digital nonlinear average pulse frequency meter containing a series of stable frequency generator and the first element AND, a series-connected adder, a measurement time counter, control trigger,. The second element And and the counter with adjustable conversion factor, the output of which is connected to the first input of the adder, the second input of the first element And is connected to the input of the second element And, as well as the measuring counter - entered the counter with a fractional conversion factor and subtraction unit, the output of which connected to the input of the measuring counter, while the first input of the subtraction unit is connected to the first input of the adder, the second input of the last is connected to the output of the counter with a fractional conversion factor, the input of which is connected to the output row and the first element and the second input of the subtraction unit. The drawing shows a diagram of a digital nonlinear meter average frequency of the pulses. The digital nonlinear average frequency meter of pulses contains a stable frequency generator 1, elements 2 and 3, trigger control 4, meter 5 measurement time, adder 6, counter 7 with adjustable conversion factor and measuring counter 8, counter 9 with fractional conversion factor and unit Yu subtraction. Digital nonlinear average pulse frequency meter works in the following way. Before starting the measurement on the reset circuit (not shown), all the counters 5, 7, 8 and 9 and the trigger 4 of the control are reset. At the same time, the input pulses having a dependence (1) on the measured parameter from the input of the meter through the element 3 And arrive at the counter 7 with an adjustable conversion factor, where they are recalculated to the conversion factor K, which is chosen equal to. (2), where A is pre-exponential the coefficient of the calibration dependence (l) is the frequency at the output of the generator 1 of a stable frequency. At the same time, pulses from the output of the stable frequency generator 1 pass through element 2 and are fed to counter 9 with a fractional conversion factor, where they are recalculated to coefficient K-, and fed to the first input of adder 6. In the adder 6 pulses to the pulse sequence from the output of counter 7 with an adjustable conversion factor, the pulse sequence S O4 is summed from the pin code of the counter 9. At the same time, the ira pulse sequence of the output of the b-bit, which is fed to the counter, is dependent on the measured parameter The measurement time of the meter is determined by the volume of the NS time meter 5 and is equal to - (At the same time, the pulse sequence from the output of the counter 7 with an adjustable conversion factor is subtracted from the output unit I of the subtraction of two pulse sequences. As a result, the average pulse frequency the sequence at the output of the unit Yu corresponds and during the measurement time T in the measuring counter 8 will be counted the number of pulses) which is the result of measure This monotonically growing function, which X from 0 to oo changes in when the limits change from O) and has a point of inflection at x.len-l - --- (9), and around which function (7) with sufficient accuracy can be aiproksimshpzhan.ch pr my. To measure the measured parameter X from (.) To Kj, t4 in the izmirich range, it is necessary to choose a hierogib point at, 465Х ,, (NN that is achieved by setting the fractional counting coefficient of the counter 9 to V h-h (11) in units of the measured parameter, the volume of the measurement time counter Ng- must be chosen equal to -21sep to 0 ((- K.) The volume of the measurement time counter 5 can be set, for example, using the preset switches. At the same time, the linearization error N (). -X ( 13) h-ex Changes when X is changed from O to O from Ocherez-SG, | ak to O when, then through DO - ZtsA-l P tnotx For measurement in the range of change of the measured parameter from X to Xt (j The inflection point must be selected in the middle of the measurement range 0, (X, -X ,, КХ. (14) The fractional conversion factor K of counter 9 is selected from equation (I), and to obtain the result of measurement in units of the measured parameter, the volume of the time meter Ng measured must be chosen equal to N -C -i-NoUK 2tLi-- cr-nol where the NQ value is entered into the measuring counter 8 by the start of the measurement, for example, using switches n e installation GDP PY in formula vychitshaets NO (x, -Xa) (i-KKv - -) (Y.j (e) 2 (1-t), 065 (.J (17) In this sluchle. linearization error .M.No.X. (.8,, (16 When igmenenchi X from X, to, varies from - + - 0 gf, through, through O and when, through O at To - “- c / d, and then through O. ° - c / 4tnax P For example, when measuring in the measuring range from 0 to 1, the error of linearization does not exceed ± 0.25% and the course of the functional dependence (13) in (18) is completely similar to the functional dependencies of the linearization of the known meter. Medium frequency is intended to reduce the nomenclature of a unified parametric series of processing units for information on radioisotope devices, which makes it widely used in various radioisotope instruments. Formula of the invention A nonlinear digital average frequency meter of pulses containing a consistently connected stable frequency generator and the first And element, a consecutively connected adder, a measurement time counter, a control trigger, a second And element, and a counter with an adjustable conversion factor, the output of which is connected to the first input of the summator of the second input the first element I is connected to the input of the second element I, as well as the measuring circuit A sensor, characterized in that, in order to expand the measuring range, a counter with a fractional conversion factor and a subtraction unit are entered into it, the output of which is connected to the input of the measuring counter (), the first input of the subtracting unit is connected to the first adder, the second input of the last connected to the output of the counter with a fractional coefficient, the conversion, the input of which is connected to the output of the first element And and to the second input of the subtraction unit. Sources of information taken into account in the examination 1, USSR Author's Certificate No. 415798, cl. H 03 K .3 / OO, 12.23.72. 2. USSR author's certificate number 4723ОЗ, cl. Q O1 R 23 / OO, 12.25.71.