SU1441208A1 - Spectrograph - Google Patents

Abstract

This invention relates to optical spectral instrumentation. The aim of the invention is to expand the simultaneously recorded spectral region by increasing the area of the spectrogram while improving the resolution at its edges. The radiation enters the spectrograph through the entrance slit located at the focus of the light detector. A parallel beam, formed by a collimator, directs, c to a flat diffraction grating. Monochromatic radiation from the grating enters the concave mirrors of the Kametlets lens. In the focal plane of each concave mirror of the camera lens there is a two-dimensional photoreceiver. The independent orientation of the mirrors of the camera lens provides the choice of the optimal conditions for formatting the corresponding portions of the spectrogram. The ability to correct aberrations is combined with a reduction in the size of the mirrors of the camera lens, which simplifies their manufacturing technology. 1 silt

Description

one "

About 00

This invention relates to optical spectral instrumentation.

The aim of the invention is to expand the recorded spectral region by increasing the area of the spectrogram while improving the resolution at its edges.

The drawing shows the optical layout of the spectrograph,

The spectrograph contains an entrance slit 1, a collimator 2, made in the form of a concave mirror, a flat diffraction grating 3, a camera lens embedded from three independently installed concave mirrors 4-6, and photographic plates 7-9, mounted in the focal plane of the lenses 4- 6 respectively.

The spectrograph works as follows.

1 The radiation being emitted enters the spectrograph through the entrance slit 1 installed at the focus of the lens of the collimator 2. A parallel beam of rays formed by the collimator 2 is directed onto the diffraction grating 3, which forms in the direction of the dispersion a fan of monochromatic beams falling on the camera lens elements. Each of these elements builds a spectrogram in their focal planes of the corresponding sections, which are recorded on photographic plates 7–9,

The independent orientation of mirrors 4–6 of the camera provides a choice of optimal conditions for the formation of images corresponding to 1X spectrogram sections. This makes it possible to improve the image quality at the edges of the spectrogram, which is especially indifferent ifpH placement of the grating at a distance of X = 0.85 f. At the same time, the dimensions of the mirror elements used in the scheme are reduced, which is especially useful when placing the grid at a distance x 2f,

g

tO

IS

20

S

0

five

When choosing the position of the elements of the chamber mirror, it is also taken into account that the images, segments of the spectrogram formed by these mirrors should not overlap with each other. This eliminates the possible ghosting of lines in a spectrogram line, due to the fact that monochromatic

the light beam going from diffraction - - -,

grid on the adjacent edges of the mirror elements, is focused independently of each of them.

The proposed spectrograph makes it possible to obtain a high quality image of the spectrum. At the same time, an increase in the aberration correction capabilities is combined with a decrease in the dimensions of the mirror elements, which simplifies their manufacturing technology. The device can be used to disassemble unique large-size spectrographs for scientific research, as well as to improve the quality of serial spectral equipment, in particular, multichannel spectral devices for monitoring the pollution of the natural environment.

Claims (1)

Invention Formula A spectrograph containing an optically coupled entrance slit, a collimator is a flat diffraction grating made in the form of a concave mirror and a camera lens made in the form of a. at least two concave mirrors optically conjugated with two photodetectors, characterized in that, in order to expand the recorded spectral region by increasing the value of cneKTporpaMNbi with; improving the resolution at its edges, each concave mirror of the camera lens is directly optically coupled to a flat diffraction grating, with the photodetectors being two-dimensional.