RU1822932C - Afocal diffraction spectrograph of erect image - Google Patents

Abstract

Usage: a direct-sight afocal diffraction spectrograph designed for spectrophotometric studies of astronomical objects. SUBSTANCE: direct-sight afocal diffraction spectrograph contains a plane-concave lens located on the same optical axis, deflecting a prism, a dispersing element, and a camera lens. The prism directs the center wavelength of the spectrum along the optical axis of the instrument. The photoelectric analyzer is located in the focus of the camera lens and is connected to the recording unit. The collimator lens is made in the form of a flat-concave lens in a single unit with a prism. A diffraction grating is applied to the flat face of the camera lens. 1 ill. f

Description

The direct-vision afocal diffraction spectrograph is an optical instrument and can be used for spectrophotometric studies of astronomical objects.

The purpose of the invention is the elimination of aberrations, the main example of astigmatism and coma, in the spectra of observed objects.

This goal is achieved in that the direct-vision afocal diffraction spectrograph contains an optically coupled collimator lens, which is a flat-concave lens, a large-sized lens, including a positive lens with a diffraction grating deposited on a flat surface, and also a recording unit connected to the output a photoelectric analyzer located at the focus of the camera lens, and the collimator lens is made in the form of a flat-concave lens in

a single unit with a prism. The prism changes the direction of the collimated beam of rays, and the diffracted rays at the maximum light concentration are lattice parallel to the optical axis of the positive lens. In this case, the spectrum is located in the center of the field of the positive lens, where the aberrations are negligible.

The device comprises (see drawing) a plano-concave lens 1 located on one optical axis, deflecting a prism 2. a dispersing element 3, a camera lens 4. The photoelectric analyzer 5 is located in the focus of the camera lens 4 and is connected to the recording unit 6. The collimator lens and a prism made of a single block of glass. The diffraction grating 3 is applied to the flat face of the camera lens 4. All the lenses and the prism are made of K8 glass. Lens diameter and

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prism height - 62 mm. the radii of curvature of the lenses are 85 mm.

A direct-sight afocal diffraction spectrograph works as follows. An incident parallel light beam by a telescope objective (not shown) is converted to converging. The spectrograph is placed in a converging beam of light in front of the focus of the telescope. A collimator, negative lens 1, made with a prism 2 from a single glass block, converts a converging light beam into a parallel one. Behind the collimator is a plano-convex lens 4, which serves as the camera lens of the spectrograph. A transparent, diffraction grating is deposited on a flat surface from the side of the collimator 3. A parallel light beam emerging from the collimator lens falls onto the grating at an angle calculated so that after the grating the diffracted light beam goes along the axis of the telescope, i.e. along the axis of the camera. As a result, in the focal plane

At a telescope speed at the location of each star, a spectrum is obtained. The highest quality spectra are located in the center of the telescope and spectrograph floor. The photoelectric analyzer 5 converts the spectra into electrical signals that are accumulated in the recording unit. In FIG. 2 (a, b) show spectra obtained without using a prism in the collimator.

Claims (1)

SUMMARY OF THE INVENTION A direct-vision afocal diffraction spectrograph containing an optically coupled collimator lens, made in the form of a flat-concave lens, and a deflecting prism, a dispersing element, a camera lens and a photoelectric analyzer, as well as a recording unit connected to a photoelectric analyzer, characterized in that. in order to prevent aberrations, a flat-bent lens is mounted on the verge of a deflecting prism. 3 4