SU941908A1 - Device for measuring pulse average frequency - Google Patents

Description

The invention relates to the field of electrical measurements and is intended to measure the average frequency of the pulses,

Known analog meter average pulse frequency, comprising a forming cascade, consisting of an amplitude normalizer, a metering capacitor and diode keys, an integrating resistor, an integrating capacitor, permanently connected, a switch, an additional integrating capacitor, a switched switch and a buffer amplifier £ l J.

However, the implementation of two or several integration time constants requires a set of appropriate capacitors and switches.

A measurement device _Λ is known that contains an operational amplifier, an integrating capacitor, a buffer amplifier, the output of which is connected via a stacking circuit with a cc2 to the input of the operational amplifier £ 2].

However, the known device operates in a relatively narrow range of operating frequencies.

⁵ The purpose of the invention is the expansion of the range of measured frequencies by increasing and smoothly regulating the time of constant integration.

¹⁰ This goal is achieved by means of a device for measuring the average frequency of pulses containing an input driver, the output of which through the first and second resistors ¹⁵ is connected to a non-inverting input of an operational amplifier, the output of which is connected through a third resistor to an inverting input, an integrating capacitor at input ²⁰ the buffer amplifier, the output of which is connected through the fourth resistor to the connection point of the first and second resistors, introduced the fifth, sixth

941908 4 and the seventh resistors, the output of the operational amplifier through the fifth resistor connected to the input of the buffer amplifier, and the inverting and non-inverting inputs of the operational 5 amplifier connected respectively through the sixth and seventh resistors with the output of the input driver and a common bus.

Figure 1 shows the electrical circuit diagram of the device; figure 2 - timing diagram of stresses.

The meter contains an input driver 1, an operational amplifier 2, a buffer amplifier 3, an- (5 tag capacitor 4, and resistors 5-11

The device operates as follows.

Upon receipt of signal pulses of ₂₀ owls (Fig. 2a) at the input of the former 1, the output of the latter shows normalized portions of charge from each input pulse (Fig. 2 (57. Resistors 6,7 and 8, ₂₅ are equal.

If the voltages at the output of the input driver 1 and at the output of the buffer amplifier 3 are not equal, i.e. a certain voltage increment appears at the output of the input shaper ΔΙ), due to the presence of feedback, a signal appears at the connection point of the resistors 8 and 9. This signal through the voltage divider (resistors 10 and 11) is fed to the non-inverting input of the operational amplifier 2 and acts in antiphase with the signal supplied to the inverting input of the same amplifier. As a result, at the first moment of time, the voltage change at the output of the operational amplifier 2 is less than expected (Fig. 2 ^).

The integrating circuit with its time constant fulfills this reduced increment, the feedback signal changes, the voltage difference between the output of the buffer amplifier and the output of the forming stage decreases, etc. to a new steady state. Thus, the presence of feedback allows one to obtain a signal operating in antiphase with a change in the signal-55 la at the output of the input driver 1 and to slow down the reaction of the integrating circuit to this change, which is equivalent to an increase in the time constant of the integrating circuit. The voltage at the output of amplifier 3 is shown in FIG. 2C; the voltage diagrams at the output of amplifier ’2 and at the output of amplifier 3 in the absence of feedback and a voltage divider are shown in FIG. 3 <?» E ·

The use of the proposed meter average pulse frequency instead of the known one allows you to expand the range of measurement of low frequencies by increasing the integration time constant in. Yu or more times. . The construction of the meter according to this functional diagram allows you to increase the time constant without increasing the resistance and capacitance of the elements of the integrating circuit.Performing a voltage divider on a variable resistor eliminates the error in measuring both the average frequency and its derivative and provides smooth adjustment of the integration time constant. The regulation range of the integration constant is (1t10) RC.

Claims (2)

1. Matveev V., .V., B. Kazanov. 2. USSR author's certificate Instruments for measuring ionizing W 691875, cl. QGG 7/18, 1976. 7 6 CZb at -t-l five CZD0l / f. | 11иШ1Ж 1ШШ1Ш V v t