SU246935A1 - THE CONVERTER OF THE FREQUENCY OF THE FOLLOWING OF THE ILSHULS IN THE VOLTAGE - Google Patents

Description

There are various frequency converter circuits. One of the most common is the circuit with the use of a standby pulse generator, normalized in amplitude and duration. Triggering pulses are applied to the input of this generator at the frequency of the input signal, and the output is connected to a filter. The output of the filter is a voltage proportional to the input frequency. With a rapidly varying input signal, such a frequency converter has a large dynamic error.

For higher performance, a frequency converter has been proposed that contains a generator of hyperbolic pulses. In this converter, each input pulse triggers a key circuit connecting a storage capacitor with a functional voltage generator (hyperbolic voltage), where the arrival time of the previous pulse is taken as a zero point. When a storage capacitor is connected to a hyperbolic voltage generator, a potential inversely proportional to the current period and, therefore, proportional to frequency, is transmitted to the capacitor.

accurate hyperbolic stress generator.

The aim of the invention is to provide such a pulse frequency to voltage converter which would provide high accuracy in combination with high speed. To achieve this, the described frequency converter is characterized by the fact that in a feedback circuit between the output memory capacitor and the key circuit as a switch phase detector, the integrator is turned on with a threshold device at the output.

FIG. 1 shows the general scheme of the described converter; in fig. 2 is a diagram of voltages and currents.

The converter consists of a function generator / current, a switch phase detector 2, an output storage capacitor 3, an integrator 4 and a differentiating circuit 5.

The input signal is formed as a sequence of alternating polarity pulses (Fig. 2, i). The positive pulses of the input signal trigger the functional generator 1 (Fig. 2.6), which realizes the piecewise-exponential time dependence of the current and the output. At the same time, the same pulses trigger the integrator 4

(Fig. 2.0), which integrates the output voltage to a given fixed level, but a reset occurs. The voltage from the output of the integrator 4 through the differentiating circuit 5 is not transmitted to the commutator phase detector 2 in the form of a pulse (Fig. 2, d), where it is compared in phase with the input negative pulse. In this case, the switch phase detector 2 connects the function generator to the output memory capacitor 5 for the time of phase mismatching in the direction corresponding to the sign of the phase difference. After the integration of each current pulse (Fig. 2.5), the storage capacitor 5 sets a voltage proportional to the frequency in a given clock cycle. The output voltage is shown in FIG. 2, e.,

Subject invention

Pulse-to-voltage frequency-to-voltage converter containing a functional current generator, a key circuit and an output storage capacitor, stating that, in order to simultaneously increase accuracy and speed, there is a feedback circuit between the output storage capacitor and the key circuit made in form of switch

phase detector, included the integrator with a poropovym device at the output.