SU661385A1 - Meter of intervals between centers of pulses - Google Patents

Description

I

The invention relates to a radio measuring technique and can be used to create devices for measuring time intervals.

A device for measuring intervals between pulse centers is known, comprising differentiating circuits, a switch, time interval meters, triggers and a recording unit 1.

Such a device has a reliable result only when one measured pulse is within the limits of another.

The closest technical solution to this invention is a device for measuring intervals between midpoints of pulses of arbitrary length, containing differentiating circuits, keys, a frequency divider, a pulse counter, a HE element, a pulse generator, and a positive pulse separator 2.

A disadvantage of this device is the limited range of measurable intervals. This is due to the fact that if the measured pulses overlap in time, the measurement result will be incorrect. In addition, for the operation of the device, it is necessary that one of its inputs

always only the first (and not the second) impulse.

The aim of the invention is to expand the range of measured intervals of the interval meter between the midpoints of the pulses.

Claims (2)

The goal is achieved by the fact that the meter measures the midpoints of the pulses, contains a pulse generator, the output of which is connected to the first input of the first key and through the frequency divider to the first input of the second key, and the outputs of the first and second keys are connected to the counting input of the reversible pulse counter, the first and the second differentiating circuit, a reversible pulse counter is additionally introduced, two converters of opposite polarity pulses into unipolar and an “exclusive OR” element, the output of which is connected to the second input of the second key, the first input of the "exclusive OR" element, connected in series to the first differentiating circuit and the first converter of bipolar pulses into unipolar, is connected to the subtractive input of an additional reversible pulse counter, the summing input of which is connected through the series of bipolar pulses to unipolar across in series and the second differentiation, the th circuit is connected to the second input of the element "exclusive OR, the first output of the additional reverse a pulse counter connected to the control input of the reversible pulse counter, and the second output optional reversing pulse counter connected to the second input of the first key. FIG. 1 shows the structural block scheme of the proposed meter intervals between the midpoints of the pulses; in fig. 2 - time diagrams of the meter. The interval meter between the midpoints of the pulses contains a pulse generator 1, a frequency divider (two) 2, keys 3, 4, an exclusive OR 5 element, differentiating circuits 6, 7, converters of different polarity pulses into unipolar 8, 9, reversing pulse counters 10 , 11, and input rails 12, 13. Before starting the measurement, the counters 10 and 11 are in the zero state. The content of the reversible counter 11 is changed to ' 1 at the moments when the front and rear edges of the measured pulses are received at the input slit 12 and 13. At the same time, the content of the reversible counter 11 increases at the moments of the beginning and end of the measured pulse arriving at the input bus 13, and decreases at the moments of the beginning and end of the measured pulse arriving at the input bus 12. The counting pulses for the reversible counter 11 are formed the input of differentiating circuit 7 and the converter 9 of opposite-polarity pulses into unipolar, and on the subtractive input - differentiating circuit 6 and the converter 8. Signal from one output of the reversing counter 11 controls the counting direction of the reversible counter 10. Depending on the sign of the number recorded in the reversing counter 11 and, accordingly, on the voltage level at its control input, the reversible counter 10 performs summation or subtraction of pulses arriving at its counting input from the key outputs 3, 4. For example, if the counter 11 contains a positive (negative) number, then the counter 10 performs summation (subtraction) of the pulses arriving at its counting input. The signal from the other output of counter 11 controls key 4. In this case, key 4 is opened only when the counter And contains the number "2 (positive or negative). When measuring, six options are possible for the location of the measured pulses relative to one another. FIG. 2 for each variant depicts: a pulse arriving at the meter bus 13; the impulse arriving on the tire 12 gauge; the contents of the counter 11; counting pulses arriving at the counting input of counter 10 (pulses depicted above the axis arrive when counter 10 is operating in the summation mode, and pulses depicted below the axis when the counter 10 is operating in subtraction mode). The meter works as follows. Consider the case when the measured pulses do not overlap in time (Fig. 2a). The impulse arriving at the bus 13 of the meter passes through the element 5, the signal at the output of which is present when only one of its inputs has an RSV signal. This pulse opens the key 3 and the clock pulses of the generator 1 arrive through divide 2 frequencies into two and key 3 into the counting input of the reversible counter 10. At the same time, the counter 10 operates in the summation mode, since the counter 11 contains the number "+ b. Since the frequency of the clock pulse arriving at the input of the counter 10 during the measured pulse is f / 2, and when filling the time interval between the pulses f, we can assume that the actual start of the measurement starts from the middle of the first measured pulse. At the end of the first measured pulse by the differentiating circuit 7 and the converter 9, a second counting pulse is generated, which arrives at the summing input of the reversing counter 11. At the same time, the contents of the counter 11 will become two (Fig. 2a) and open the key 4, which will pass the clock pulses to the input counter 10 during the pulse time interval. When the leading edge of the second measured pulse arrives on the bus 12 of the meter, the differentiating circuit 6 and the converter 8 form a counting pulse, which is fed to the subtracting input of the counter 11 and reduces its content by one. In this case, the key 4 is closed, and the key 3 is opened by the second measured pulse, which arrives at the control input of the key 3 through the element 5. Again, for the duration of the measured pulse, the counter inputs of the counter 10 will receive clock pulses that equivalent to the end of the measurement in the middle of the second measured pulse. Thus, at the end of the measurement, the counter 10 will contain a number proportional to the interval between the centers of the measured pulses. The sign of the contents of the counter 10 will depend on which of the input fields of the meter will receive the first measured pulse. Now consider the operation of the meter, when the measured pulses overlap in time (Fig. 2c, g d, e). In this case, the contents of counter 11 will not be in absolute value greater than “1, and therefore key 4 will always be closed. For the specificity of the description of the work from the measurer, consider the case of FIG. 2c. The forefront of the measured pulse arriving on the bus 13 is the first. Therefore, the reversible counter 10 is set to the mode "summation." During the time interval between the leading edges of the measured pulses, clock pulses with a repetition frequency f / 2 arrive at the input of the reversible counter 10, since the key 3 is opened by the voltage from the output of the element 5. When a second measured pulse appears on the meter bus 12, the output of element 5 disappears voltage, opener, its key 3, and the clock pulses at the input of the counter 10 are not received. If now the front edge of the measured pulse arriving on the bar 12 (Fig. 2c) is the first, then the contents of the reversible counter 11 will become equal to -1 and the counter 10 will operate in the subtraction mode. During the time interval between the falling edges of the measured pulses, pulses with a frequency of f / 2 arrive at the input of the counter 10. Thus, at the end of the measurement, the counter 10 will contain a number proportional to the half-difference of the intervals between the front and rear edges of the measured pulses, which is equal to the interval between the midpoints of the measured pulses. Thus, the difference between the midpoints of the measured pulses in the case shown in FIG. 2d For the measurement options shown in FIG. 2d and fig. 2e, at the end of the measurement, the counter 10 will contain a number proportional to the half-sum of the intervals between the leading and trailing edges of the measured pulses, which in these cases is equal to the interval between the midpoints of the measured pulses. Only in the case shown in FIG. 2d, the number will be negative, since the middle of the pulse arriving on the bus 12 is ahead of the middle of the pulse arriving on the bar 13 of the meter. The invention The interval meter between the midpoints of the pulses contains a pulse generator, the output of which is connected to the first input of the first key and through the frequency divider to the first input of the second key, and the outputs of the first and second keys are connected to the counting input of the reversible pulse counter, the first and second differentiating circuit, characterized in that, in order to expand the range of measured intervals, a reversible pulse counter is additionally introduced into it, two converters of different polarity pulses p and the element "exclusive OR, the output of which is connected to the second input of the second key, and the first input of the element" exclusive OR through a series-connected first differentiating circuit and the first converter of different polarity pulses into unipolar connected to the subtractive input of an additional reversing pulse counter, the summing input of which through serially connected second converter of bipolar pulses into unipolar and second differentiating circuit is connected to the second input of the element is the "exclusive-OR output of the first additional pulse reversible counter is connected to a control input of the reversible pulse counter, and the second output optional reversing pulse counter connected to the second input of the first key. Sources of information taken into account during the examination 1. USSR author's certificate No. 275851, cl. G 04 F 10/04, 1967. 2. USSR author's certificate number 251088, cl. G 01 R 23/02, 1967. 661385