SU900211A1 - Device for measuring amplitude modulated pulse train envelope phase - Google Patents

Description

The invention relates to radar and is intended to measure the phase difference between the envelope of the amplitude-modulated pulse sequence and the reference modulating signal.

A device is known consisting of series-connected envelope detector, multiplier and integrator [1].

. The disadvantage of this device is that the result of the phase measurement depends on the pulse repetition period.

Closest to the proposed technical essence and the achieved result is a device for measuring the phase envelope of an amplitude-modulated pulse sequence containing a series-connected amplitude detector, filter and phase detector [2].

However, in the device, the phase shift of the extracted envelope of the pulse signal at the filter output relative to the true envelope of the input signal depends on the pulse repetition period, which leads to measurement errors when the pulse repetition period changes.

The purpose of the invention is to improve the measurement accuracy when changing the pulse repetition period.

This goal is achieved by the fact that in a device for measuring the phase envelope of an amplitude-modulated pulse sequence containing a series-connected first amplitude detector, a first filter and a phase detector, series-connected limiter amplifier, amplitude modulator, second amplitude detector and second filter, the output of which connected to the second input of the phase detector, and the input

The amplifier-limiter is connected to the input of the first amplitude detector, and the control input of the amplitude modulator is the reference input of the device.

The drawing shows a structural * block diagram of a device for measuring the phase of the envelope of an amplitude-modulated pulse sequence.

The device contains a series-connected first amplitude detector I, a first filter 2 and a phase detector 3, as well as series-connected amplifier limiter 4, an amplitude modulator 5, a second amplitude detector 6, a second filter 7, the output of which is connected to the second input of the phase detector 3. The inputs of the first amplitude the detector 1 and the amplifier of the limiter 4 are interconnected and are the signal input of the device, and the control input of the amplitude modulator 5 is the reference input of the device.

The device operates in an ice-comfortable way.

The inputs of the first amplitude detector I and amplifier-limiter 4 receive an amplitude-modulated pulse sequence, the pulse duration of which is much less than their repetition period.

For example, consider the case of sinusoidal modulation. At the output of the first amplitude detector 1, the envelope of the pulse sequence is selected, which has the form of a step function, the magnitude of the steps being determined by the amplitudes of the corresponding pulses of the sequence. The signal from the output of the first amplitude detector 1 is fed to the input of the first filter 2, the parameters of which are selected optimal for the modulating signal. At the output of the first filter 2, a modulating signal is generated, which is input to the first input of the phase detector 3. The input signals are amplified and limited in the amplifier-limiter 4. From the output of the amplifier limiter 4, pulses with a constant amplitude are fed to the input of the amplitude modulator 5, to the control input whose reference signal is a sinusoidal voltage with a frequency equal to the frequency of the modulating signal 5 of the pulse sequence. From the output of the amplitude modulator 5, the amplitude-modulated pulses are fed to sequentially connected amplitude detector 10 6 and a second filter 7, the parameters of which are identical to those of the first amplitude detector 1 and filter

2. At the output of the second filter 7, a converted reference signal (sinusoidal voltage) is extracted, which is fed to the second input of the phase detector 3. Phase detector 3 measures the phase difference between the envelope of the amplitude-modulated 20 pulse sequence and the converted reference signal.

The phase shift of the envelope to the trigger of the filter depends on the pulse repetition period, so when the repetition period changes, the shift also changes. However, in this device, when the repetition period changes, both the envelope and the converted reference signal are simultaneously shifted in phase equally. Consequently, the phase difference measured by the phase detector

3 is independent of the pulse repetition period, which increases the measurement accuracy.

Claims (2)

1. Theoretical foundations of radar location. Ed. 1% 9maia Ya.D. M., Soviet radio, 1970, p. 296. FIG. 5. 59. 2. Skolnik M. Introduction to the technique of radar systems. Per. from English, ed. Trofimova K.N., M., Mgr, 1965, p. 216-218 (prototype). D