RU172395U1 - SIMULATOR OF OPTICAL SIGNALS OF IR AND UV SPECTRUM RANGE FOR TUNING AND INSPECTION OF OPTICAL ELECTRONIC TRACKING SYSTEMS - Google Patents

Abstract

The invention relates to the field of optical instrumentation and relates to a simulator of optical signals in the IR and UV ranges. The simulator includes a source of incoherent radiation, neutral and spectral filters, a condenser, a diaphragm, a movable wedge-shaped curtain, a parabolic mirror, a scanning mirror and a translucent plate. In addition, the simulator contains an IR radiation source, a first aperture, a neutral filter, an optical switch, a counter-mirror, a second parabolic mirror connected to the second input of the translucent plate. The simulator also includes a second source of incoherent radiation, a second diaphragm, a first oblique mirror, and a second oblique mirror connected to the second input of the optical switch. In addition, the simulator contains a photometric ball, interchangeable test objects, a disc with interchangeable neutral filters, an inclined mirror — a spectral filter, a third parabolic mirror, and a third inclined mirror connected to the input of the beam splitter plate, to the other input of which radiation previously summed on the translucent plate is supplied from sources of infrared and incoherent radiation. The technical result consists in providing the possibility of taking measurements simultaneously in the IR and UV ranges. 1 ill.

Description

The proposed device relates to the field of optical instrumentation and can be used to verify and adjust the energy parameters and operation of passive-type multichannel optoelectronic tracking systems (OESS) as part of control equipment in the conditions of experimental and serial production of products.

It is known, for example, the device [1] - patent for utility model No. 131372, publ. 08/20/2013, containing a serially connected electric drive, a reducer, a mirror swing mechanism, a protective glass, a parallel beam simulator connected in series, an inclined mirror, the output of which is connected to a swing mirror input, an angular displacement transducer, an information processing unit, a photometric ball, test object, the output of which is connected to the input of the parallel beam simulator, the output of the information processing unit is connected to the input of the electric drive. And the output of the swinging mirror mechanism is connected to the input of the angular displacement transducer.

The device [1] is designed to test the functioning of single-channel passive-type OESS in the UV range of the spectrum in the field in accordance with a given sequence diagram without the possibility of varying the verification modes. To configure multichannel OECSs containing IR and UV channels, this device cannot be used in laboratory and workshop conditions.

The closest in its technical essence to the proposed utility model is a simulator of optical signals in the infrared range for tuning and checking the OECS [2] - certificate of the Russian Federation for utility model No. 27952, publ. 02/27/2003, selected as a prototype.

The device [2] contains a series-connected source of incoherent radiation, a neutral filter, a spectral filter, a condenser, a fixed diaphragm, a movable wedge-shaped curtain, a parabolic mirror, a scanning mirror, a translucent plate, a series-connected IR source, a diaphragm, a neutral filter, an optical switch, a counter-mirror , a parabolic mirror, the output of which is connected to another input of the translucent plate, a series-connected source of incoherent radiation, d an aperture, a first oblique mirror, a second oblique mirror, the output of which is connected to another input of the optical switch, a control panel and a DC motor connected in series, the output of which is simultaneously connected to the inputs of the drive mechanism of the movable wedge-shaped curtain and the mirror scanning mechanism, the output of which is connected to the kinematic input scanning mirror, and the output of the mechanism is connected to the kinematic input of a movable wedge-shaped curtain.

The device [2], selected as a prototype, cannot be used for tuning and testing multichannel OESS containing IR and UV channels in laboratory and workshop conditions, since it contains only one source of the IR spectrum range.

The task to which the utility model is directed is to improve the noise immunity of the OESS from natural background formations due to the possibility of carrying out complex tuning and verification of multichannel OESSs simultaneously in the IR and UV spectral ranges.

To solve this problem, we propose a simulator of optical signals in the IR and UV spectral ranges for tuning and checking the OECS, which, like the one closest to it, selected as a prototype, contains a serially connected incoherent radiation source, a neutral filter, a spectral filter, a condenser, and a fixed diaphragm , a movable wedge-shaped curtain, the first parabolic mirror, a scanning mirror, the output of which is connected to the first input of the translucent plate, a source connected in series To radiation, the first diaphragm, a neutral filter, an optical switch, a counter-mirror, the second parabolic mirror, the output of which is connected to the second input of the translucent plate, the incoherent radiation source connected in series, the second diaphragm, the first oblique mirror, the second oblique mirror, the output of which is connected to the second input optical switch, connected in series with the control panel and a DC motor, the output of which is simultaneously connected to the inputs of the movable drive mechanism wedge-shaped curtains and mirror scanning mechanism, the output of which is connected to the kinematic input of the scanning mirror, and the output of the drive mechanism of the movable wedge-shaped curtains is connected to the kinematic input of the movable wedge-shaped curtain.

A feature of the proposed utility model that distinguishes it from the known device is that the simulator of optical signals of the IR and UV spectral ranges for tuning and checking the OECS is arranged to accommodate four interchangeable test objects connected in series with an additionally introduced photometric ball, a disk with six interchangeable neutral filters, an inclined mirror - a spectral filter, a third parabolic mirror, a third inclined mirror, the output of which is connected to the input hydrochloric splitter plates, the other input of which receives the radiation previously summarized in the semitransparent plate of the IR radiation source and a source of incoherent radiation.

The essence of the utility model lies in the fact that the proposed simulator of optical signals in the IR and UV spectral ranges for tuning and testing the OECS additionally includes a source of ultraviolet radiation - a photometric ball with built-in test objects, which made it possible to configure and verify the parameters of not only the IR channel, but also the UV OESS channel in laboratory and workshop conditions. In addition, the presence of test objects built into the photometric ball and a disk with six replaceable neutral filters made it possible to change the contrast sign (positive - negative) of the target simulator and to regulate the irradiation from the UV radiation source in a wide range, which is necessary when setting the OECS.

The essence of the proposed technical solution is illustrated by the drawing.

The simulator of optical signals in the IR and UV ranges of the spectrum for tuning and checking the OECS in laboratory and workshop conditions contains:

1 - source of incoherent radiation,

2 - neutral filter,

3 - spectral filter,

4 - condenser

5 - fixed aperture,

6 - movable wedge-shaped curtain,

7 - the first parabolic mirror,

8 - scanning mirror,

9 - translucent plate,

10 - source of infrared radiation,

11 - the first diaphragm,

12 - neutral filter

13 - optical switch

14 - counter-mirror,

15 is a second parabolic mirror,

16 - beam splitting plate,

17 - source of incoherent radiation,

18 - the second diaphragm,

19 - the first inclined mirror,

20 - second inclined mirror,

21 - the third inclined mirror,

22 - the third parabolic mirror,

23 - tilt mirror - spectral filter,

24 - a disk with six replaceable neutral filters,

25 - test objects

26 is a photometric ball,

27 - remote control

28 - DC motor,

29 - the drive mechanism of the movable wedge-shaped curtains,

30 is a mirror scanning mechanism.

A simulator of optical signals in the IR and UV spectral ranges for tuning and checking the OECS works as follows.

The sources of radiation of the main channel, the simulator of the IR range, are either an IR source 10, which uses an absolutely black body (AFC) with a cavity temperature of 573 K, or a second incoherent radiation source 17, which uses a TRSh2850 lamp with a brightness temperature of the filament 1500 ° C. The first diaphragm 11 limits the cross section of the radiation beam of the IR source 10, and the second diaphragm 18 defines the second source of incoherent radiation 17. To attenuate the radiation from the blackbody, a attenuator is introduced — a neutral filter 12. The first oblique mirror 19 and the second oblique mirror 20 combine the axis of the second radiation beam incoherent radiation source 17 with the axis of the radiation beam of source 10. From the output of the optical switch 13 through the counter-mirror 14, the second parabolic mirror 15 and the beam splitter plate 16 to the input half the pupil plate 9 from the channel of the IR range of the spectrum receives a parallel beam of radiation from the source of IR radiation 10 or from a second source of incoherent radiation 17.

The radiation source of the UV channel of the spectrum is a photometric ball 26, where three lamps of the KGM 12-100 type are used as a source. Four interchangeable test objects 25 allow you to change the sign of the contrast of the target - the background. In the case of setting the OECS, test objects 25 are used as a dark dot on a light background, and test objects 25 as a light dot on a dark background are introduced to measure the irradiation from the UV channel using standard measuring instruments. The difference in the size of the points of the test objects 25 of the same contrast allows one to change the irradiation of the UV channel by an order of magnitude. A smooth change in irradiation is provided by six replaceable neutral filters in the disk 24. Inclined mirror - spectral filter 23 selects the UV range from the broad spectrum of the radiation of the photometric ball 26, the collimated beam reflected from the third parabolic mirror 22 enters the third inclined mirror 21, and then to the input of the beam splitter plate 16, the reflective coating of which introduces additional filtering of the UV spectrum.

Thus, the simulator implements two main IR channels that enter the inputs of the translucent plate 9, followed by summing with the UV channel at the inputs of the beam splitter plate 16.

The moving interference simulation channel is constructed as follows. The light flux from the first source of incoherent radiation 1, which is used as a TRSh 2850-3000 lamp, is fed through a neutral filter 2 to the input of the spectral filter 3. At the output of the spectral filter 3, the blackbody radiation spectrum is simulated with a temperature of 1700 K in the spectral sensitivity ranges of the main and auxiliary channels of the verified OECS. The capacitor 4 projects the extended filament of the lamp of the first source of incoherent radiation 1 into the plane of the fixed diaphragm 5. Through the openings of the fixed diaphragm 5, the light flux enters the first parabolic mirror 7. The movable wedge-shaped curtain 6 moves relative to the fixed diaphragm 5 and determines the number of holes through which the light flux will arrive to the first parabolic mirror 7 and then to the scanning mirror 8. By a signal from the control panel 27, a direct current motor 28 is driven, output which is connected to the input drive mechanism 29, the movable wedge and the inlet shutter mechanism 30, the scanning mirror. In order for each of the optical interference to occur at one point of the focal plane, the slice moving speed of the movable wedge-shaped shutter 6 along the axis of the openings of the fixed diaphragm 5 is chosen equal to the speed of image movement of each hole of the fixed diaphragm 5 and directed in the opposite direction. From the output of the scanning mirror 8, the moving images of optical noise are fed to the input of the translucent plate 9, followed by summing with the radiation of either the IR channel or the UV channel of the simulator on the beam splitter plate 16.

Thus, the task aimed at improving the noise immunity of the OECS from natural background formations, due to the possibility of carrying out complex tuning and testing of multi-channel OECS simultaneously in the IR and UV spectral ranges, has been solved.

Claims (1)

A simulator of optical signals of the IR and UV spectral ranges for tuning and checking the OECS, containing a sequentially connected incoherent radiation source, a neutral filter, a spectral filter, a condenser, a fixed diaphragm, a movable wedge-shaped curtain, a first parabolic mirror, a scanning mirror, the output of which is connected to the first input of a translucent plates, a series-connected source of IR radiation, the first diaphragm, a neutral filter, an optical switch, a counter-mirror, a second parabolic mirror A halo whose output is connected to the second input of a translucent plate, a source of incoherent radiation, a second diaphragm, a first oblique mirror, a second oblique mirror, the output of which is connected to the second input of the optical switch, are connected in series to the control panel and a DC motor, the output of which is simultaneously connected to the inputs of the drive mechanism of the movable wedge-shaped curtain and the scanning mechanism of the mirror, the output of which is connected to the kinematic input by scanning mirror, and the output of the drive mechanism of the movable wedge-shaped shutter is connected to the kinematic input of the movable wedge-shaped shutter, characterized in that the simulator is arranged to accommodate four interchangeable test objects connected in series with additionally introduced photometric ball, a disk with six interchangeable neutral filters, an inclined mirror - a spectral filter, a third parabolic mirror, a third inclined mirror, the output of which is connected to the input of an additionally introduced beam splitter Lastin, to the other input of which receives the radiation previously summarized in the semitransparent plate of the IR radiation source and a source of incoherent radiation.

Images