RU1809368C - Device for stabilizing energetic axis of radiation beams - Google Patents

Abstract

The invention relates to measuring technique and allows to increase the accuracy of stabilization of the energy axis of linearly-polarized radiation beams and to reduce stabilization losses. The purpose of the invention is to improve the accuracy of stabilization. The device comprises a linearly polarized radiation source, for example a gas laser, the radiation beam of which, passing through the collimator and converted from a diverging to a parallel one, is incident on a beam-splitting prism, where it is divided into 2 beams. The transmitted radiation beam is directed to a half-wave plate, where its polarization plane is rotated, the polarizer, and, passing through the Glan-Thompson polarization prism, is incident on a position-sensitive photodetector. 1 ill.

Description

The invention relates to measuring technique and can be used to measure deviations from the linearity of centering objects using devices that use the energy axis of a beam of linearly polarized optical radiation, in particular laser, as a reference line.

The aim of the invention is to increase the accuracy of stabilization of the energy axis of linearly-polarized radiation beams.

The drawing shows a General view of the device. A device for stabilizing the energy axis of light beams consists of a linearly-polarized radiation source 1, for example, a gas laser installed in the housing 2 with quotation screws 3, a collimator 4 and located on the base of the optical element block. This unit contains an input beam splitting prism b and an output polarizing prism, for example, a Glan-Thompson prism 7, mounted so that the optical axis of the prism components is perpendicular to the plane of polarization of the radiation beam passing through the input prism.

In the gap between these prisms, a half-wave plate 8 is fixedly mounted, as well as a rotary polarizer 9, mounted on the base 5 with the possibility of a turn when assembling the device.

In the path of the radiation beam reflected by the input prism 6, a reflective prism 10c is mounted with a roof. Between prisms 6 and 7 and reflective prism 10 on the side,

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A film polarizer 11 is mounted on the opposite roof-side face of the prism 11. The base 5 is fixed in the housing using fixing screws 12 and adjusting screws 13.

The radiation beam emerging from the Glan-Thompson prism is directed to a position-sensitive photodetector 14 mounted on a controlled product.

The device operates as follows:

A linearly polarized radiation source, such as a gas laser, emits a beam of radiation that, passing through the collimator 4, is converted from diverging to parallel. Known focal optical systems of Kapler or Galile can be used as a collimator. The resulting parallel beam of radiation falls on the input beam-splitting prism 6, where it is divided into 2 beams.

The radiation beam passing through the prism. 6 then passes through the half-wave plate 8, where the plane of its polarization rotates through 90 °, the polarizer 9, the output Glan-Thompson prism 7, and enters the position-sensitive photodetector 14.

Since the plane of polarization of this radiation beam passing through the Glan-Thompson 7 polarization prism is parallel to the optical axis of the elements of this prism, this radiation beam passes through the prisms 7 completely without experiencing reflection from the plane of separation of the elements of the prism 7.

The radiation beam reflected from the input beam-splitting prism 6 passes through the film polarizer 11, which reflects the prism 10 with the roof, again passes through the film polarizer 11 and falls on the dividing face of the Glan-Thompson prism 7. Since the plane of polarization of this radiation beam is perpendicular optical axis of the elements of the prism 7, then this radiation beam is completely reflected from the dividing face of the prism 7 and is combined with the radiation beam passing through the input beam-splitting prism 6.

Due to the fact that these radiation beams have mutually perpendicular directions of the polarization planes, then

their combination does not cause spurious interference.

The film polarizer 11 is installed when the block is glued in the position 5 of maximum transmission of the radiation beam through it and serves to compensate for the loss of light when it passes through the rotary polarizer 9.

The exact equalization of the power of the radiation beams entering and leaving the polarizing prism is made when the device is assembled by turning the polarizer 9, in which the power of the beam passing through it changes

5 radiation. The alignment of the radiation beams emerging from the polarization prism is achieved by adjusting the position of the base 5 in the housing 1 with the help of adjusting screws 13.

0 The device allows to increase the accuracy of stabilization of the energy axis of the radiation beams by eliminating losses in the combination of beams, as well as by eliminating spurious reflection of beams

5 radiation from the walls of the device. SUMMARY OF THE INVENTION A device for stabilizing the energy axis of radiation beams, comprising a base, sequentially installed collimated radiation source

and located with a gap from one another

and designed to form in the gap. Two spatially separated

radiation beams two prisms, the first of

5 of which, in the direction of radiation from the source, a beam splitter is made, a half-wave plate and a polarizer installed with the possibility of rotation relative to the plane of polarization of the radiation of the source,

0 registration unit, it is noteworthy that, in order to increase the stabilization accuracy, it is equipped with a reflective prism installed in the path of the radiation beam reflected from the beam splitter prism with

5 with a roof and a film polarizer located between two prisms and a prism with a roof on the side opposite the roof-shaped face, and the second along the radiation prism is made in the form of a polarization prism, for example, a Glan-Thompson prism, and is oriented so that its optical axis components perpendicular to the plane of polarization of the radiation beam passing through the beam beams 5

prism.