RU2011153529A - METHOD FOR PROVIDING CONSTANT DISTANCE CAPABILITY BY DISTANCE IN A PULSE RADAR STATION WITH A QUASI-RANDOM PHASE MODULATION - Google Patents

Abstract

A method consisting in emitting one LFM pulse and processing the reflected pulses with a matched compression filter, characterized in that when receiving reflected pulses, the duration of which is less than or equal to the duration of the probe pulse, in order to ensure the measurement of distances to targets with constant resolution over the entire range and for simultaneous measurement of radial velocities of targets, the emitted pulse consists of several time sections with successively decreasing duration, internal of each time interval, the signal samples are sampled with a frequency F> 2F and calculated digitally according to the law of frequency modulation within the frequency range from zero to the deviation frequency F, then they are rearranged in a quasi-random manner in time, forming a phase-modulated sequence of samples, these samples are then converted to voltage, which is passed through a low-pass filter that limits the modulation frequency band to the ΔF≥F band, from the filter output the signal is transferred to the carrier frequency f, amplified by power and transmitted to the antenna for radiation, the reflected pulses received by the antenna are amplified, filtered at the carrier frequency f by a band-pass filter with a passband ΔF, are sampled in time with a frequency F≥2ΔF with the condition f = nF + ΔF / 2, n = 1, 2, 3, ... and quantized by level, then the actual digital samples of the signal by digital quadrature heterodyning are transferred to zero frequency, the complex results of heterodyning are processed by a digital complex low-pass filter with a passband ΔF, at

Claims (1)

A method consisting in emitting one LFM pulse and processing the reflected pulses with a matched compression filter, characterized in that when receiving reflected pulses, the duration of which is less than or equal to the duration of the probe pulse, in order to ensure the measurement of distances to targets with constant resolution over the entire range and for simultaneous measurement of radial velocities of targets, the emitted pulse consists of several time sections with successively decreasing duration, internal each time segment of the signal samples, sampled at a frequency F _f> 2F _ninth and calculated in digital form by the law of frequency modulation within the frequency changes from zero to a frequency deviation F _nine, then permuted in time quasi-randomly, forming the phase-modulated sequence of samples, these samples are then are converted into a voltage that is passed through a low-pass filter, limiting the modulation frequency band to a band ΔF _m ≥F _dev , from the filter output the signal is transferred to the carrier frequency f ₀ , amplifying is transmitted by the power and transmitted to the antenna for radiation, the reflected pulses received by the antenna are amplified, filtered at the carrier frequency f _{0 by a} bandpass filter with a passband ΔF _m , time discretized with a frequency F _d ≥2ΔF _m with the condition f ₀ = nF _d + ΔF _m / 2, n = 1, 2, 3, ..., and are quantized by level, then the actual digital samples of the signal are transferred to the zero frequency by digital quadrature heterodyning, the complex results of heterodyning are processed by a digital complex low-pass filter A signal with a passband ΔF _m , samples are generated at the filter output with a repetition rate F _c ≥ΔF _m , which are then processed by a compression filter whose impulse response in terms of duration, phase modulation function and expected Doppler frequency shift is consistent with the reflected pulse.