SU692377A1 - Method of optical treatment of impulse-doppler radiologication station signal - Google Patents

Description

Surrounding device 2, which consists of an optical disk 3 and a chip-shaped diaphragm: as well as an astigmatic system 5, a multi-channel time integrator 6, an indicator 7, while on a rotating optical disk 3 on a spear optical ROKKalvf recorded periodic structures with different spatial frequencies, with a stOM on an optical disk 3, two structures are recorded in each with the same spatial frequencies, so that as the disk 3 rotates, the phase of one structure increases and the phase of the other decreases. In addition, the structures of different spatial jj frequencies are located so that their frequencies vary linearly along the radius of the optical disk 3, and the number of perviduses in each structure is equal to or a multiple of the number of periods of the intermediate frequency o in the CRT 1 along the first coordinate. dinat, for example along the x- coordinate. The astigmatic system 5 is set so that it projects a multi-channel target. A new time integrator 6 is a plane 25 that is remote from the plane in which the optical transducer 2 is located.

The method of optical processing of the signature of the pulse-Doppler radar station is carried out as follows.

The signal of an impulse-Doppler radar station at an intermediate frequency is converted into a light-modulated light signal using a capacitive 35 CRT I electrode, and a CRT 1 frame and line scan is rotated along a single coordinate, for example, V, SIR-40 deployed with a clock frequency of the radar signal, and on another X coordinate, the signal is deployed synchronously with an intermediate frequency.45

As a result of the sweep of the signal along the coordinate%, the wavelength elevations of the signal move from one clock frequency to another, with the speed and direction of their movements depending on the magnitude and sign of the Doppler shift signal relative to the intermediate frequency.

Then, using an optical converter 2, the signal that is deployed along the X coordinate is converted into another light 55, the phase of the spatial structure of which along the coordinate is proportional to the asynchrony of the spatial structure692377

Signal tours along the X coordinate with the CRT 1 along this coordinate at all points of the signal's tracking frequency, i.e. phase spatial

the structure of the converted signal is proportional to the difference in frequency of the signal from the intermediate frequency in magnitude and sign. As a result of this operation, at a certain distance from the output plane of the optical transformer 2, a correlation function is formed in the incoming light between the light signal generated by the CRT 1 and each spatial structure on the optical disk 3. By projecting the correlation function plane onto the multichannel target with an astigmatic system 5 the time integrator b along the X axis, and the screen of the CRT 1 along the y axis, at the same time using the optical disk 3 and the slit diaphragm 4, perform signal spectral analysis using the optical disk 3 in time at all points of the sweep along the X coordinate at the clock frequency of the signals, while the signal at the multichannel time integrator b. maximum on that frequency channel of the optical disk 3, for which the frequency and sign of the phase change of its spatial structure coincides with the spatial frequency and direction of the light signal moving along the X coordinate on the CRT screen 1. The signal from the multi-channel time integrator b is read and output to the indicator 7 The velocity form in the coordinates is the frequency of Dopaler - range;

Thus, in the proposed method, the spectral analysis of the signal is performed in the range of the signal's clock frequency (0.01-10 kHz), which is significantly lower than the intermediate frequency range (kHz), which allows for more accurate reference time frequencies and consequence, improve the accuracy of determination of Doppler frequencies. In order to provide analysis in the range of the clock frequency of the signal, the proposed method introduced the X-coordinate signal sweep operation synchronously with the intermediate frequency and the optical conversion of this signal into the Other. The simultaneity of the transformation and spectral analysis operations is necessary for performing spectral analysis over time.

Claims (1)

Invention Formula A method of optical signal processing of a dimple-doppleroic radio broadcasting standardy at an intermediate frequency by means of a pogoem converting an electrical signal into modulated RCOS. -. a light signal that is developed (in the plane along the first axis with a clock frequency of the signal following), and the spectral analysis of the light signal in time simultaneously at all points of the first axis, which, with the aim of increasing the accuracy of determining the Doppler frequency, is signal is deployed to The PLANE along the second axis is synchronized with the npcv intermediate frequency and is converted into a second signal, the phase structure of which is proportional to the non-synchronous spatial structure of the signal along the second axis with an intermediate frequency at all points of the first axis, while spectral analysis is performed one-time with the operand neither Sources of information adopted during the examination 1. United States Patent No. 3483557, cl. 0159 / О4. 1970.