RU2016132761A - METHOD FOR PRODUCING A SCALAR VORTEX BEAM AND DEVICE FOR ITS IMPLEMENTATION - Google Patents

Claims (4)

1. A method of obtaining a scalar vortex beam includes obtaining a phased array of N collimated Gaussian beams parallel to each other, the centers of which are uniformly distributed along the perimeters of geometric figures having a common center of symmetry, by controlling N phase-shifting elements included in the positive feedback circuit and controlled in accordance with the algorithm of stochastic parallel gradient descent, characterized in that the formation of a composite beam with a central zero intensity with a nonzero orbital moment, the magnitude of which is controllable, quickly tunable, and lies in the range [-N / 3, N / 3], it is carried out by controlling the phase of each beam and maintaining such a phase state of the system for a long period of time. 2. The device for obtaining a scalar vortex beam includes a coherent source of linearly polarized radiation, a radiation divider into N channels of equal power associated with N optical phase-shifting elements that regulate the phase of the optical wave, each of the N channels has N collimators at the output, all N collimators are configured in parallel and form a synthesized beam, part of the radiation of which is deflected using the first beam splitter plate, characterized in that it has a second beam splitter plate, dividing the beam and into 2 equal parts, and it contains two control circuits that operate alternately, the first of which contains a photodetector equipped with a point aperture and the first controller to bring the individual beams into a state with the same phase, and the second circuit includes a second controller for generating phase shifts specifying the orbital angular momentum and a photodetector equipped with a diaphragm with an overlapped central zone to determine the moment of time according to the criterion for transferring control to the first controller. 3. The device according to claim 2, characterized in that the centers of the radiation sources can be located on one or more concentric circles. 4. The device according to claim 2, characterized in that the device can have hexagonal and square packaging without having the source in its center.