SU683013A1 - Method of frequency to d-c conversion - Google Patents

Description

; hm1pulses of current of stable area, filter 4, load 5, conversion: 1 ton, in periods to voltage, voltage storage device 7, function converter 8 in our current inversely proportional to current.

The amplifier / produces amplification and limitation of the input signal. The imaging unit 2 forms short impulses that trigger the capacitor dispenser 3 and the period converter 6 to voltage. With the arrival of the triggering pulse, the capacitor metering unit generates a current of a stable area, and the period-to-voltage converter works in the following sequence: it sends output to the device 7 to the output for the time required to terminate the iBO transient of the input circuit of the device 7, then is reset to its original state (zero voltage n output) and begins to generate a very time-varying voltage with a constant slope before the arrival of the next trigger pulse, after its generation is stopped, and the process is novtor. In device 7, a voltage proportional to the period is indicated. This voltage is converted by the functional converter 8 to the inversely proliferation current value. The obtained current value, directly proportional to the frequency, is used as a pump to form 3 current pulses of a stable area supplied to the load 5, clamped by the filter 4 and connected through the dispenser 3 in series with the output of the functional converter 8. In the load 5 from the sequence formed by the dispenser 3 current-area pulses of a stable area are allocated an average value of the current directly proportional to the value of the frequency at the input of the converter. After the first pinning pulse of the input signal, a minimum (zero) voltage level is transmitted to the device 7 from the output of the converter 6, which is remembered by the device 7 until the second input pulse arrives. In this case, at the output of the functional converter 8, the current has a maximum value, and, therefore, the dispenser 3 transmits to the load a current pulse of a stable area with a maximum amplitude. After the arrival of the second input pulse, the converter 6 transmits to the device 7 a voltage proportional to the laser pulse between the first and second pulses. This voltage is remembered by device 7 for the duration of the second

period (before the arrival of the third pulse input). At the output of the functional converter 8, the current decreases from the maximum value to the value inversely proportional to the first period. With the arrival of the second input pulse, the dispenser transmits to the load a current pulse of the same area as the first measured pulse, but with a Less amplitude, inversely proportional to the first period. Thus, with an abrupt supply, as well as with abrupt changes in the input frequency, the duty cycle of current dischargers of a stable area, fed to the load, is set to close to one (with a rectangular shape) with a delay of one period of the input signal. Due to the fact that current pulses of a stable area, dosed into the load, have an automatically maintained close to one unit ratio, with a rectangular shape, in order to extract the average current and suppress parasitic pulsations with the proposed method of converting frequency to current, significantly less inertia filters are required than with the known method. This makes it possible to significantly improve the speed and extend the frequency range in the low frequency region while maintaining high accuracy of conversion.

Claims (2)

1.Novitsky P.V. and others. Digital devices with frequency sensors. - M., Energie, 1970, p. 282. 2. Baranov L. A., et al. Condenser converters in automation and control systems. - M., Energie, 1969, p. 6