RU2755004C1 - Method for visualised testing of infrared bolometric systems - Google Patents

Abstract

FIELD: testing.

SUBSTANCE: method can be used in remote verification of the orientation of the optical axis of an infrared bolometer and the amplitude-pulse characteristics of the electronic path thereof in infrared optoelectronics, systems for verification and configuration of apparatuses for high-speed heat control of high-velocity objects and visual targeting of the infrared beam. The method includes irradiating the tested bolometric system with infrared and visible radiation and analysing the infrared ray using an information system. To irradiate the tested bolometric system, pulsed infrared radiation of a crystal laser with longitudinal semiconductor laser pumping is used, the visible radiation whereof is partially used to visualise the infrared beam.

EFFECT: technical result is the increased testing accuracy and time resolution of infrared bolometric systems.

1 cl, 1 dwg

Description

The invention relates to the field of testing infrared bolometric systems that control the thermal state of power units and mechanisms, namely, to remote verification of the orientation of the optical axis of an infrared bolometer and the amplitude-pulse characteristics of its electronic path and can be used in infrared optoelectronics, systems for verification and adjustment of high-speed thermal devices control of high-speed objects and visual target designation of the infrared beam.

The known method [1] contactless testing of infrared bolometers, in which two diffuse emitters made in the form of rings with different temperatures, a Foucault knife, a collimator and a meter for measuring the difference in radiation temperatures. Foucault's knife is made in the form of a mirror prism of an asymmetric profile, the working edge of which is located in the focal plane of the collimator. One face of the prism is optically connected with the first emitter, and the other with the second. The prism is installed with the possibility of linear and angular movements in a plane perpendicular to the optical axis of the collimator and along this axis. One of the emitters is made with the possibility of regulating its temperature. The infrared spot formed in this way on the tested receiver of thermal radiation allows changing the structure and spectral characteristics of the thermal spot. This is determined by the speed at which the prism moves. At the same time, this method also does not have sufficient speed, since the prism mechanics has a limitation in the frequency of the reciprocating motion. But the main fundamental disadvantage of this method is the impossibility of visualizing the infrared spot when testing thermal radiation receivers.

The known method [2], in which infrared radiation from a source through a condenser, modulator, photometric wedge irradiate the tested, for example, a receiver of thermal radiation (lens with a bolometer). A collimator lens for visualization projects an image of a heat ray onto a sensitive target of a pyrovidicon transmitting tube, in which a signal is generated to obtain a television image of an infrared heat spot at the entrance of a bolometric lens. The principal advantage of this method in comparison with [1] lies in the visualization of an infrared thermal infrared ray. In this method of testing optical systems operating in the infrared region of the spectrum, the mechanical modulator of thermal radiation is limited in the frequency of interruption of the infrared radiation. This is due to the speed limit of the motors of the modulator units. So, for example, for testing bolometric temperature control systems for axleboxes of a high-speed (300 km / h) railway train or blades of jet turbines, the modulator engine must have 10,000 and 30,000 rpm. In reality, such a mechanical modulator is practically unrealizable. Thus, this method of testing in the infrared region of the spectrum of optical systems, having visualization of a heat ray on a target of a pyrovidicon transmission tube for obtaining a television image of an infrared heat spot, has a registration speed limitation. This is a significant disadvantage of this method.

The closest technical solution to the proposed one, taken as a prototype, is a method [3] for testing, research and alignment of any optical systems operating in the infrared region of the spectrum. The essence of the method lies in the fact that the tested infrared bolometric system is irradiated with thermal pulses of an infrared photoluminescent crystal emitter with an accompanying visible glow. Infrared and accompanying visible luminescence of a crystalline emitter (Er: BaY ₂ F ₈ crystal) is excited by pulsed radiation of a semiconductor laser through a hole in a concave and flat condenser mirror. In a single pulsed thermal and accompanying visible beam formed by the mirror condenser, the spatial intensity distribution corresponding to the spatial intensity distribution of the thermal spot on the tested bolometric system is visually observed. The pulsed laser exciting the crystal emitter is controlled by a microprocessor-based programmable device that sets the repetition rate, duration and amplitude of infrared and accompanying visible pulses. Electrical pulse signals from the infrared bolometric system under test are fed to a digital oscilloscope and information system for analysis and presentation of test results.

The aim of this invention is to create a method that allows you to increase the testing accuracy and time resolution of infrared bolometric systems.

Comparative analysis with the prototype allows us to conclude that the technical solution meets the “novelty” criterion.

The applicant is not aware of the following features from the prior art:

1. The duration of a pulse of thermal and visible radiation of a crystalline laser is significantly shorter than the pulse duration of a photoluminescent crystal emitter for the tested infrared bolometric systems.

2. On the bolometer window, the cross-sectional area of the visualized thermal laser beam is much smaller than the beam area of the photoluminescent crystal emitter.

Thus, the claimed technical solution meets the criterion of "inventive step". In addition, with the interaction of signs, a new technical result is obtained - the testing distance of infrared bolometric systems is significantly increased.

Figure 1 shows a block diagram of a device for implementing this method.

The method is carried out as follows.

The infrared bolometric system under test (0) is irradiated with a pulsed laser that generates a single beam of thermal and visible radiation. Infrared laser radiation is generated by an active crystalline (Er: BaY ₂ F ₈ ) medium (1) in a cavity formed by flat dielectric mirrors (4-4 '). Longitudinal pumping of an Er: BaY ₂ F ₈ crystal (1) is performed by pulsed visible radiation of a semiconductor laser (2) through a mirror (4 '), which almost completely transmits the pump radiation, but almost completely reflects the stimulated infrared radiation of the crystal. A semitransparent mirror (4) is the output for infrared and visible laser pumping radiation. In the formed pulsed laser thermal and visible single beam, the spatial intensity distribution corresponding to the spatial intensity distribution of the thermal spot on the tested bolometric system is visually observed. The pulsed pump laser (2) of the Er: BaY ₂ F ₈ crystal (1) is controlled by a microprocessor-based programmable device (5), which sets the repetition rate, duration and amplitude of laser infrared and accompanying visible pulses. Electrical pulse signals from the infrared bolometric system under test (0) are fed to a digital oscilloscope (6) and an information system (7) for analysis and presentation of test results.

Example 1. The tested infrared bolometric system - the BP-2 bolometer (sensitivity range 1.9-10 microns) with a germanium collecting lens 1.5 cm in diameter, is irradiated at a distance of 3.5 m with thermal pulses of an infrared crystal laser with a wavelength of 2.9 microns with accompanying blue pumping radiation at a wavelength of 457 nm. A blue visualizer of an infrared spot with a diameter of 0.3 cm is directed to the center of a germanium lens. The microprocessor system sets the heat pulse repetition rate of 50 Hz, the duration (5 ms) less than the temporal resolution (10 ms) of the tested bolometric system with an amplitude corresponding to half of the saturation level of the amplifying system of this bolometer. At the output of the tested bolometric system using a digital oscilloscope, a sequence of electrical impulses with a repetition rate of 50 Hz with a duration of 10 ms and an amplitude of half the dynamic range is recorded. In a direct experiment, testing confirmed the performance (10 ms) of an infrared bolometric system based on the BP-2 bolometer. The bolometer test alignment clearly shows that the center of the infrared spot alignment will coincide with the visible imaging image. Despite the considerable distance between the emitter and the bolometric system, this result confirms that in a single beam the accompanying pulsed visible light has practically the same spatial intensity distribution as in a thermal beam.

In contrast to the prototype, in this example, the thermal beam of the crystal laser is directed to the center of the germanium lens of the infrared bolometric system at the center of the blue imaging spot. Thus, a higher accuracy of adjustment and testing is achieved, since the diameter of the laser spot (0.3 cm) is 5 times smaller than the diameter of the radiation spot (1.5 cm) of the prototype. Thus, in comparison with the prototype, the accuracy of testing infrared bolometric systems is significantly increased.

Example 2. The tested infrared bolometric system - a fast (0.5 ms) bolometer based on lead sulfide FSV-16A (sensitivity range 1.0-3.2 μm) with a germanium collecting lens 3 cm in diameter is irradiated at a distance of 10 m with thermal pulses of an infrared crystal laser with a length wavelength of 2.9 μm with accompanying blue pumping radiation at a wavelength of 457 nm. A blue visualizer of an infrared spot with a diameter of 0.4 cm is directed to the center of a germanium lens. The microprocessor system sets the heat pulse repetition rate of 1 kHz, the duration (0.5 ms) equal to the time resolution of the tested bolometric system and the amplitude corresponding to half of the saturation level of the amplifying system of this bolometer. At the output of the tested bolometric system using a digital oscilloscope, a sequence of electrical pulses with a repetition rate of 1 kHz and a duration of 0.5 ms in amplitude in half the dynamic range is recorded. In a direct experiment, testing confirmed the performance (0.5 ms) of an infrared bolometric system based on lead sulfide FSV-16A.

In the prototype, the testing distance reaches 2.5 m. Thus, in comparison with the prototype, without reducing the time resolution, the testing distance for infrared bolometric systems is increased by 4 times.

Example 3. The tested infrared bolometric system - a fast (1 μs) infrared bolometer based on indium arsenide Hamamatsu P8079-01 (sensitivity range 1.0-3.6 μm) with a window diameter of 0.5 cm is irradiated at a distance of 3.5 m with thermal pulses of an infrared laser with wavelength 2.9 μm with accompanying blue pumping radiation at a wavelength of 457 nm. A blue visualizer of an infrared spot with a diameter of 0.3 cm is directed to the center of the window of a Hamamatsu P8079-01 infrared bolometer. The microprocessor system sets the heat pulse repetition rate of 1 kHz, with a duration (1 μs) equal to the time resolution of the tested bolometric system. At the output of the tested bolometric system using a digital oscilloscope, a sequence of electrical pulses with a repetition rate of 1 kHz and a duration of 1.0 μs is recorded and synchronously, by processing the amplitude values of the pulse sequence by an information computer system, the passport dynamic range of an infrared bolometric system based on indium arsenide Hamamatsu is confirmed with an error of 5% P8079-01. The tests carried out confirmed the temporal resolution (1.0 μs) and the passport dynamic range of the infrared bolometric system based on indium arsenide Hamamatsu P8079-01. In the prototype, the temporal resolution is 0.5 ms. Thus, in comparison with the prototype, the speed of testing infrared bolometric systems is increased 500 times.

Thus, the achievement of the object of the invention has been confirmed experimentally. The use of the proposed invention in comparison with the known invention provides the following advantages:

- increasing testing accuracy

- increasing the testing distance

- increasing the temporal resolution of testing

Sources of information

1. Patent of the Russian Federation No. 2042124. A device for measuring optical parameters of optoelectronic devices. From 20.08.1995 Cl. G01M 11/02. Chugunov A.V .; Fedyunina S.A .; Novoselov V.A.

2. Patent of the Russian Federation No. 2024000. A device for controlling the quality of the optical system. From 12.05.1991, Cl. G01M 11/02. Zaritsky A.A., Kolobrodov V.G., Kucherenko O.K., Kovalenko L.A.

3. Patent of the Russian Federation No. 2428671. Method for testing infrared bolometric systems. From 10.09.2011 Cl. G01M 11/02. Baryshnikov V.I., Krivorotova V.V.

Claims (1)

A method of visualized testing of bolometric systems, including irradiation of the tested bolometric system with infrared and visible radiation and analysis of the infrared beam by an information system, characterized in that pulsed infrared radiation of a crystal laser with longitudinal pumping by a semiconductor laser is used to irradiate the tested bolometric system, the visible radiation of which is partially used for visualization infrared ray.

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