SU1164774A1 - Simulator of starry sky - Google Patents

Abstract

The STAR SKY IMITATOR, containing a lens, an eyepiece, a reticle and a light source, a condenser, a pinhole mirror, a translucent mirror and a beam deflection assembly, consistently installed on the same optical axis, is characterized in that, in order to simplify and improve the simulation quality, the beam deflection assembly consists from a set of iris diaphragms with opaque curtains and a rectangular prism with mirror edges installed with the possibility of changing their relative position. O) 4

Description

The invention relates to star system models and can be used in performance testing and calibration of star sensors in laboratory conditions.

A starry sky simulator containing a lens, an eyepiece, a light source, a condenser, a pinhole, a translucent mirror and a beam deflection assembly, is well known. It makes the manufacture of a deflection assembly for each star system simulated and does not correct the spectral composition of the radiation. complex and insufficiently high-quality imitation process.

The purpose of the invention is to simplify and improve the quality of imitation.

The goal is achieved by the fact that a simulator of a starry sky containing a lens, an eyepiece, a reticle and a source of light, a condenser, a point diaphragm, a translucent mirror and a beam deflection assembly consistently on the same optical axis, the beam deflection assembly consists of a set of iris diaphragms with opaque curtains and right angle prisms with mirror edges installed with the possibility of changing their relative position.

The drawing shows a schematic diagram of the simulator

Starry sky simulator contains light source 1, condenser 2, pinhole 3, installed in the focal plane of lens 4, light filters 5, iris diaphragms 6, cse

thin shutters 7, deflecting mirrors 8, rectangular prism 9 with mirrored edges A and B for autocollimations. The beam of light reflected by the mirror face A of the prism 9 is focused by the lens 4 using a translucent mirror 10 in the focal plane with the sight 11 of the eyelet 12, while the translucent mirror 10 is located at the intersection of the optical axes of the lens 4 and the eyepiece 12. The deflecting mirrors 8 have the ability to move along the propagation of light beams and change the orientation relative to the mirror face A of the prism 9 by means of the turning mechanisms 13. The iris diaphragms form a beam deflection unit with a rectangular prism.

The simulator works as follows.

A beam of light from light source 1, collimated by lens 4, passes through light filters 5, iris diaphragms 6 and falls on deflecting mirrors 8. The planes of deflecting mirrors are at calculated angles to each other and to the mirror face A of a rectangular prism 9. These angles corners correspond to the distance of the simulated configuration of stars. The light clusters reflected from each surface of the deflecting mirrors 8 create a collimated set of light beams, each of which simulates one star. Having illuminated the lens of the star sensor in the focal plane with the indicated beams of light, an image of the simulated star system is obtained.

To accurately set the deflection assembly on the optical axis of lens 4, a beam of light reflected from the mirror face A of a rectangular prism 9 is used and using a translucent mirror 10 focused by lens 4 into a focus plane with a sight 11 ocul 12.

To simplify the alignment of tunable star sensors relative to the simulator using the autocollimation method, the mirror face B of the rectangular prism 9 is used. Combining the mirror surfaces into a single prism element 9 makes it easy for the simulator to simplify its alignment relative to the star sensor and increase its accuracy.

For the spectral imitation of stars in beams of light falling on the deflecting mirrors B, light filters 5 are installed, which correct the spectral composition of the radiation.

, To simulate the stellar magnitudes in the beams of light falling on the deflecting mirrors 8, iris diaphragms 6 are installed, restricting the flow in the rays of light.

. To change the adjustment to other parts of the starry sky, deflecting mirrors that are not used in the imitation of star systems are closed with opaque rods 7. 31164774 The invention allows the reproduction to drive angular precision with great precision. dimensions, brightness, spectral radiation and angular positioning. ra. .4 simulated stars in razrazuchastnyh sky without any changes imitato design

Claims (1)

A STARRY SKY SIMULATOR comprising a lens, an eyepiece, a sight, and a light source, a condenser, a pinhole, a translucent mirror and a beam deflection unit sequentially mounted on the same optical axis, characterized in that, in order to simplify and improve the quality of imitation, the beam deflection unit consists of from a set of iris diaphragms with opaque curtains and a rectangular prism with mirror faces installed with the possibility of changing their relative position. A '1164774