SU1099341A1 - Optical device for forming directional pattern - Google Patents

Abstract

OPTICAL DIAGRAM EDUCATIONAL DEVICE, containing a flat antenna array, the elements of which are connected to the corresponding channels of the space-time light modulator installed in the front focal plane of the first collecting lens, in order to form the output image on an exponential scale of elevation and linear in azimuth, a second collecting lens is inserted into it, the front focal plane of which is aligned with the rear focal plane of the first collecting lens, and the amplitude The single-phase transparency installed in the back focal plane of the first collecting lens, the transparency being defined by the formula a gp Ti..hn; xpj, -Kp.3, b.jL / -i, .i, w ,, I о Chy J / X and where - the coordinates of points in the plane of the transparency; i k - 14 unit; -wave radio wave number; kDVli60d; R o D - diameter flat antenna 1 of the array; Ud is the mean square error of beamforming; rfw-p k f - integration variables; - wave number of a light wave; focal length of the first collecting lens; m, i and, m co with the ratio of the dimensions of the antenna array and the space-time light modulator along the corresponding axes. 4

Description

The invention relates to radio engineering, in particular to acousto-photoelectronics, and can be used in antenna and acoustic systems. An optical diagramming device is known that contains a space-time light modulator (PVMS), whose channels are connected to the corresponding elements of a flat antenna array (AP) and installed in the front focal plane of the converging lens, allowing parallel viewing of space by forming solid fan of radiation patterns (yes) 1. However, the output image of such devices is formed in the coordinates of the direction cosines, which does not allow realization of pattern recognition, invariant to scale and rotation. The closest to the proposed technical entity is an optical diagramming device comprising a flat AP, the elements of which are connected to the corresponding channels of a PVMS installed in the front focal plane of the collecting lens, the rear focal plane of which is output 2. A disadvantage of the known device is that it does not allow to realize pattern recognition, scale and rotation inverse, since its output image is formed in the coordinates of the guiding mows nousov. The purpose of the invention is to form an output image on an exponential scale in elevation and linear in azimuth. The goal is achieved by the fact that in an optical beamforming device containing a flat AP, the elements of which are connected to the corresponding channels of the space-time light modulator, installed in the front focal plane of the first lens assembly, the second lens of the front focal plane is aligned with the rear focal plane of the first lens assembly, and the amplitude-phase transparency, installed in the rear focal plane of the first collecting lens, with transparency the transparency determines with the formula 0-2JI T (A,) J jeKp | -ikR j expcicosp.i - () (b, where X and y are the coordinates of points in the plane of the transparency; i is the imaginary unit; k is the wave number of the radio wave ; RP. KDV UTbOL; D is the diameter of the flat antenna array; W is the specified root-mean-square error in the formation of the radiation pattern; {. And / 3 are the integration variables; K is the wave number of the light wave; f is the focal distance of the first collecting lens; t and t, are the ratios of the sizes of the antenna array and the space-time modulator of the light according to the corresponding axes. Agen diagram of an optical beam forming apparatus. The proposed optical beamforming device comprises a flat AP 1, the elements of which 2 are connected to the corresponding channels 3 of the PVMS 4 installed in the front focal plane of the first collecting lens 5, the rear focal plane of the first collecting lens 5 is aligned with the front focal plane of the second collecting lens 6, the rear focal plane dtft plane, which is the output. In this case, an amplitude-phase transparency 7 is installed in the common focal plane of the first and second collecting lenses 5 and 6. The radio emission source 8 with the angular coordinates o is displayed in the output plane as a light spot 9. The optical diagram of the generating device works as follows. The signals received by the elements 2 of the flat PA 1 control the corresponding channels 3 of the PVMS 4, thereby forming (when the latter is illuminated with collimated light) the optical model of the received radiation. As a result of the Fourier transform, the first collection of lens 5 in its posterior focal plane xy reproduces the angular distribution of sources located in the far field of the YR, in the form of diffraction spots that coincide in shape with the DF AR in the coorinates of the cosine guide cos d cos p. The amplitude-phase transform 7 and the second assembly and lens 6 transform the image obtained on an exponential scale in elevation and in a linear azimuth. To understand the latter, we note that with the kRg / (kD) 2 / fleol parameter of the systems of the first and second collecting lenses and the amplitude-phase transparency 7, the light signal is transformed after the PVMS 4 with a purely exponential argument function exp ot. Therefore, the indicated convolution with an accuracy of. By is equivalent to the Fourier transform on an exponential scale exp about the elevation.

Thus, the device allows the output image to be formed on an exponential scale in elevation and linear in azimuth.

Claims (1)

(54.) OPTICAL DIAGRAM FORMING DEVICE containing a flat antenna array, the elements of which are connected to the corresponding channels of the space-time light modulator installed in the front focal plane of the first collecting lens, characterized in that, in order to form the output image on an exponential scale on an exponential scale elevation angle and in a linear azimuth, a second collecting lens is introduced into it, the front focal plane of which is aligned with the rear focal plane of the first collecting lens, and amplitude - a phase transparency installed in the rear focal plane of the first collecting lens, wherein the transparency of the transparency is determined by the formula a rn where x and 7 are the coordinates of the points in the transparency plane; i is the imaginary unit; k is the wave number of the radio wave; R ₀ ? kD7lfl60a; D is the diameter of the flat antenna G of the array; ^'10 Ud - the set mean square error of beamforming; and β are integration variables; K is the wave number of the light? ’Wave; f is the focal length of the first collecting lens; ПЦ и - the ratio of the sizes of the antenna array and the space-time light modulator along the corresponding axes.