SU1339470A1 - Prism - Google Patents

Abstract

This invention relates to physical optics. used to convert the azimuth position of the plane of polarization of the linearly polarized radiation into radiation with a transverse scan of the variable azimuth of polarization. The purpose of the invention is to improve the accuracy and sensitivity of the conversion. The prism parallelepiped is composed of elements 2 and 3, made of oppositely rotating modifications of an optically active crystal with an optical axis 4. Element 2 is made in the form of a prism with an isosceles triangle in the main section. Element 3 complements element 2 to the rectangular parallelepiped. For this prism there are two positions with identical polarizations symmetrically spaced relative to the middle zone. 2 Il. e (L with CO with 4: O Phage. /

Description

The invention relates to physical optics devices for analyzing polarized radiation, namely to convert the azimuth of the polarization of linearly polarized radiation into radiation with transverse scanning of the variable azimuth of polarization.

The purpose of the invention is to improve the accuracy and sensitivity of the conversion of the polarization azimuth to the transverse scan.

FIG. 2 shows the projection of the prism and the position of the polarization plane of the linearly polarized radiation transmitted through it; in fig. 2, section A-A in FIG. .

The converter is made in the form of a composite prism-parallelepiped 1 of two elements 2 and 3, which are made of oppositely rotating modifiers of an optically active crystal with an optical axis 4 oriented orthogonal to the input and output faces of the prism 1, while one element 2 is made in A prism with a triangular main section, the face of which, passing through the base of this triangle, is the entrance, and the second element 3 is made in the form of an addition to the first to the rectangular parallelepiped. The dimensions h and hj of elements 2 and 3 along axis 4 along the center of the parallelepiped prism are equal to each other h h / ,.

The device works as follows.

Linearly polarized luminous flux with a selected position of the polarization plane (for example, vertical, as in Fig. 1) falls normally on a prism paralelepiped 1-. When a prism enters the optically active medium), the polarization plane of the light flux begins to rotate: this rotation becomes more and more, the longer the path passes in the specified medium Depending on the modification of the crystal, the polarization plane is rotated in one direction or the other.

Sequential passage of the luminous flux of elements 2 and 3, made of media with different directions of rotation, lead / g to turn

the polarization plane determined by the difference in the paths of light in each medium. As a result, in each section of the parallelepiped prism, except for the middle one, there is a rotation determined by the difference in the thickness of the prism elements. In the middle part, where h h, there is no rotation of the polarization plane.

Thus, the fixed position of the polarization plane of the input beam corresponds to the output luminous flux with the position of the polarization plane that is variable over the field of the light zone (Fig. 2). At the same time, for this prism there are two positions with identical polarizations, symmetrically rotated relative to the middle zone by a total distance of -2B. The use of symmetrically located zones with identical positions of the polarization plane allows not only to increase the sensitivity of the transformation, but also to increase accuracy by eliminating errors due to the tilt of the beams. The symmetric arrangement of the zones with identical polarization in the inclined beams gets a linear displacement, but the distance ex between them remains unchanged, which creates the invariance of the sweep to the inclination of the beams.

Claims (1)

Formula from the found and A prism made as a composite prism parallelepiped of two elements that are made of oppositely rotating modifications of an optically active crystal with an optical axis oriented orthogonal to the input and output faces of the prism, the dimensions of the elements along the axis along the center of the prism parallelepiped are equal to each other , characterized in that, in order to increase the resolution and accuracy, one element is made in the form of a prism with an isosceles triangle in the main section, the face of which, passing through of the base of the triangle, it is input, and the other element is a complement of the first element to the rectangular parallelepiped.  j / / 4-t / / / Fcl.2