SU530301A1 - Optical birefringent compensator - Google Patents

Description

This is achieved by the fact that in the proposed compensator comprising a movable component dvupuchepreloml generating component configured as a connected plate and wedge and wedge birefringent component to wedge component attached an additional plane-parallel birefringent guide plate, the optical axis is perpendicular to the optical axis of the V-component and the composite component is made of birefringent material with a disperse birefringence and sleep that is different from the material of the wedge component The bi-directional movement mechanism is kinematically associated with the movement mechanism of the wedge component.

In contrast to the Soleil compensator, the proposed compensator has an uneven field, so a compensator is installed on the compensator, fixed to the body, and an ocular p through which the interference pattern is observed and the compensation band coincides with the thread (just as Babin’s compensator does).

The fabrication of compensator components from different birefringent materials and the ability to control the ratio of their thicknesses by changing the gear ratio allows the dispersion birefringence of the compensator to be set, and the simultaneous movement of both components with a constant ratio of their thickness while maintaining the value of the dispersion.

The drawing shows a schematic diagram of the compensator.

The compensator has two birefringent components 1 and 2 made of birefringent media with different birefringence dispersions. The first component contains a plane-parallel plate 3 and a wedge 4, the second component is similar to a wedge 5 and a pyoscope-parallel plate 6.

The optical axes of the birefringent media from which the wedges are made are parallel to each other, perpendicular to the optical axes of plates 3 and 6, and perpendicular (or parallel) to the edges of the wedges. The working surfaces of the plates and one of the working surfaces of the wedges are parallel to the optical axis (the directions of the optical axes. In the drawing are shown dots and arrows). The thickness of the plate of each component is equal to the thickness of the wedge in the middle section. The angles of the wedges are equal, the directions of the wedges are opposite.

Each component is provided with means of movement 7 and 8 in a direction perpendicular to the edges of the wedges. Means of movement are connected by kinematically transmission 9, the gear ratio of which is regulated, for example, discretely by means of alternately included pairs of cylindrical gears.

Near the surface of the plate 6 there is a reperial thread 10, parallel to the edge of the wedge and stationary relative to the body. Behind the thread there is a polarizer 11, the direction of transmission of which makes an angle of 45 ° with the optical axes of the platinum. The interference pattern is observed through the ocul tr 12.

This dispersion with controlled dispersion ensures measurement accuracy not more than 1%.

Claims (1)

Invention Formula Optical birefringent compensator containing a composite birefringent component made in the form of a joined plate and a wedge, and a wedge birefringent component equipped with a displacement mechanism, characterized in that, in order to improve accuracy and extend the range of measurements, an additional birefringent plate is attached to the wedge component , the optical axis of which is perpendicular to the optical axis of the wedge component, and the composite component is made of birefringent material with tlichnoy material from wedge component dispersion of birefringence and movement mechanism is provided which is kinematically associated with the mechanism of movement of the wedge component.