RU108653U1 - INFRARED COLLIMATOR - Google Patents

Abstract

 1. An infrared collimator containing a lens placed in the focal plane of the infrared collimator in front of a background emitter equipped with an actuator, a temperature meter of the worlds, the output of which is connected to the first input of the device for stabilizing the level of contrast radiation, the output of which is connected to the actuator of the background emitter, characterized the fact that an additional control device is introduced into it, the output of which is connected to the second input of the device for stabilizing the level of contrast about radiation. ! 2. The infrared collimator according to claim 1, characterized in that the device for stabilizing the level of contrast radiation contains a processor, the first and second inputs of which are the first and second inputs of the device for stabilizing the level of contrast radiation, a temperature difference meter between the background emitter and the world, the output of which is connected to the third input of the processor, and the output stage, the input of which is connected to the output of the processor, and the output is the output of the device for stabilizing the level of contrast radiation. ! 3. The infrared collimator according to claim 1, characterized in that the control device is made in the form of an interface device, the output of which is the output of the control device. ! 4. The infrared collimator according to claim 1, characterized in that the control device is made in the form of series-connected master and interface device, the output of which is the output of the control device.

Description

The proposed utility model relates to optical instrumentation and is intended to control the parameters of thermal imaging devices.

A known laboratory setup for measuring the minimum resolvable temperature difference (see Lloyd D. Thermal imaging systems. M. 1978, p. 392, 393), which is a collimator containing a lens, a world, a radiator, a device for stabilizing the temperature difference between the radiator and the world having an ambient temperature.

The disadvantage of this installation is that to stabilize the required constant level of contrasting infrared (IR) radiation when the ambient temperature changes, the operator must change the temperature difference between the background emitter and the world in accordance with the dependence ΔT = F (T _m , ΔМ), where:

ΔT is the temperature difference between the background emitter and the world;

T _m - the temperature of the worlds, equal to the ambient temperature;

ΔM is the level of contrast radiation.

This dependence is determined either by calculation or by the calibration of the device in the operating range of ambient temperatures. Maintaining the required level of RT is difficult for the operator, does not allow to quickly monitor fluctuations in ambient temperature and can lead to errors.

The closest to the proposed utility model (prototype) in terms of technical nature and the achieved effect is the IR collimator (Utility Model Certificate No. 29155, CL G02B 27/30, 2002) containing a lens to the world having an ambient temperature located in the focal plane of the IR collimator in front of a background emitter equipped with an actuator, an ambient temperature meter (worlds), the output of which is connected to the input of the device for stabilizing the level of contrast radiation, the output of which is connected to solid element of the background emitter. The device for stabilizing the level of contrast radiation automatically maintains the temperature difference between the background emitter and the world at the level ΔТ = F (T _m , ΔМ). The dependence ΔТ = F (T _m , ΔM) formed in the device for stabilizing the level of contrast radiation in an analogue way is a piecewise linear approximation of the nominal dependence obtained when calibrating the IR collimator. In the IR collimator under consideration, ΔМ has one constant preset value introduced into the device for maintaining the level of contrast radiation when it is adjusted.

The disadvantage of this IR collimator is the relatively large error, up to 0.3 K at a contrast radiation level of 3 K, of the error in maintaining the level of contrast radiation with a change in the ambient temperature, due to the error of the piecewise linear approximation. In addition, this IR collimator only supports one ΔM setpoint. To change it, a reconfiguration is necessary with the replacement of pick-up electro-radio elements of the device for stabilizing the level of contrast radiation, which requires considerable labor and time costs and is often unacceptable.

The impossibility of promptly changing the level of supported contrast radiation does not allow the use of the same IR collimator to control the performance of various types of thermal imaging devices, which require different values of the contrast radiation level at their optical input, and also does not allow the use of an IR collimator to measure a number of characteristics thermal imaging devices, such as the minimum allowable temperature difference and the minimum detectable temperature difference p, in the measuring process which is necessary to maintain high levels of contrast of the radiation.

The task to which the proposed utility model is aimed is to increase the accuracy of monitoring the main parameters of thermal imaging devices by increasing the accuracy of maintaining a given value of the contrast radiation level when the ambient temperature changes, as well as expanding the functionality of the IR collimator by providing the ability to maintain different values of the contrast level radiation.

This goal is achieved by the fact that in the infrared collimator containing the lens, placed in the focal plane of the infrared collimator in front of the background emitter equipped with an actuator, a world temperature meter, the output of which is connected to the first input of the device for stabilizing the level of contrast radiation, the output of which is connected to the executive an element of the background emitter, an additional control device is introduced, the output of which is connected to the second input of the level stabilization device radiation, and the fact that the device for stabilizing the level of contrast radiation contains a processor, the first and second inputs of which are the first and second inputs of the device for stabilizing the level of contrast radiation, a temperature difference meter between the background emitter and the world, the output of which is connected to the third input of the processor, and output stage, the input of which is connected to the processor output, and the output is the output of the device for stabilizing the level of contrast radiation, as well as the fact that the control device is EHO as interface devices, whose output is the output of the control device, and in that the control device can be configured as a series-connected set point and an interface device, whose output is the output of the control device.

Figure 1 and 2 presents a functional diagram of an infrared collimator.

The IR collimator (Fig. 1) contains a lens 1, the world 2, located in the focal plane of the IR collimator in front of the background emitter 3, equipped with an actuator 4, a temperature meter 5 of the world 2, the output of which is connected to the first input of the device 6 for stabilizing the level of contrast radiation, the output which is connected to the actuator 4 of the background emitter 3, a control device 7, the output of which is connected to the second input of the device 6 for stabilizing the level of contrast radiation. The device 6 for stabilizing the level of contrast radiation contains a processor 8, the first and second inputs of which are the first and second inputs of the device 6 for stabilizing the level of contrast radiation, a meter 9 of the temperature difference between the background emitter 3 and the world 2, the output of which is connected to the third input of the processor 8, made for example, on the MSC1211 chip, the output stage 10, the input of which is connected to the output of the processor 8, and the output is the output of the device 6 for stabilizing the level of contrast radiation. The control device 7 can be made in the form of an interface device 11 (FIG. 2), for which, for example, the MAX3243 microcircuit, the output of which is the output of the control device 7, can be used. The control device 7 can also be made in the form of series-connected master 12, for example, a personal computer and an interface device 11 (Fig. 1), the output of which is the output of the control device 7. The drawings also show a controlled thermal imaging device 13.

The IR collimator works as follows.

Areas in the central part of the working surface of the background emitter 3, not covered by world 2, which can be made, for example, in the form of a thin opaque plate, in the central part of which there are a number of through slots parallel to each other (see view A of FIG. 1), located in the focal plane of the IR collimator, they are created due to a certain heating or cooling by the actuating element 4, which can be, for example, a heater or a thermionic cooler, a background emitter 3 and the temperature of the worlds 2 is at ambient temperature, contrasting, with a certain level of contrasting radiation, the infrared radiation flux, which is formed by the lens 1 and is directed to the entrance pupil of the thermal imaging device 13. In the thermal imaging device 13, the infrared contrast radiation is converted into brightness contrast in the visible region, the magnitude of which is proportional level of contrast radiation.

Maintaining a given constant level of contrast radiation when the ambient temperature changes (worlds 2) is ensured by changing according to the law ΔT = F (T _m , ΔM) the temperature difference between the background emitter 3 and world 2 and is carried out as follows.

The voltage from the output of temperature measuring device 5 of Worlds 2 is supplied to the first input of processor 8. This voltage is converted by an analog-to-digital converter (not shown in the drawings), which is part of processor 8 (microcircuit MSC1211), into the code according to which processor 8, using the previously entered and the dependence ΔT = F (T _m , ΔM), where ΔM can have different values within the operating range, is stored in its read-only memory (ROM) (not shown in the drawings) in the form of an equation or a system of equations, ΔM value, the required value (code) ΔT, corresponding to the measured temperature value of the worlds.

From the output of the temperature difference meter 9 between the background emitter 3 and the world 2, the voltage corresponding to the measured ΔT value is supplied to the third input of the processor 8, it is converted by the analog-to-digital converter included in it, and then it is compared with a code corresponding to the required ΔT value. The code calculated by the processor 8, corresponding to the difference between the required and the measured ΔT values, is converted by the processor 8 into a corresponding, for example, pulse-width-modulated signal, which, through the output stage 10, is supplied to the actuator 4 of the background emitter 3, which ensures the maintenance of the required DM level. Preliminarily, before starting work in the mode of maintaining a given level of contrast radiation, the dependence ΔT = F (T _m , ΔM) in the ROM of processor 8 is inputted by the controller 12 connected via the interface device 11 to the second input of the processor 8 and by the processor 8 itself, which provides the necessary input order dependencies in your ROM. Special equipment when you enter the dependence ΔT = F (T _m , ΔM) in the processor 8 is not required.

If the PC collimator is designed to maintain only one level of contrast radiation during operation, for example, control during operation of the characteristics of commercially available thermal imaging devices of the same type, in the ROM of processor 8, previously, in addition to setting, the dependence ΔT = F (T _m , ΔM) is entered , one value (code) ΔM corresponding to the required level ΔM, and further, when controlling the characteristics of thermal imaging devices, the setter 12 is not required. Moreover, the control device 7 includes only the interface device 11, which is necessary for connecting the setter 12 in special cases, for example, when replacing controlled obsolete thermal imaging devices with new ones with higher sensitivity, which requires installing a new, lower collimator on the optical output of the PC ΔM values. To install it, it is enough to connect any personal computer to the interface device 11, enter a new ΔM value using any medium, for example, an installation CD-ROM through the interface device 11 into the device 6 for stabilizing the contrast radiation level, and turn off the computer, whose participation in further work is not required .

If the IR collimator is designed to maintain different levels ΔM with the possibility of prompt selection of one of them, a control device 7 is used, equipped with a setter 12, with the help of which the required value ΔM can be input and can be changed quickly by the interface device 11, which allows using one IR a collimator for monitoring various types of thermal imaging devices and measuring a number of their characteristics, such as, for example, the minimum resolvable and minimally detectable temperature differences requiring x installation in a certain order of different ΔM values. Changing the supported levels ΔM in the process of measuring the characteristics can be carried out automatically in a certain order by the controller 12 in accordance with the program laid down in it. In addition, the representation of the dependence ΔT = F (T _m , ΔM) introduced into the device 6 for stabilizing the level of contrast radiation in the form of an equation or a system of equations significantly reduces (up to ± 0.03 K) the error in maintaining the required level of contrast radiation when the ambient temperature is changed in comparison with the option of forming this dependence in an analogous way (error up to ± 0.3 K), which allows to increase the accuracy of monitoring the main parameters of thermal imaging devices.

Claims (4)

1. An infrared collimator containing a lens placed in the focal plane of the infrared collimator in front of a background emitter equipped with an actuator, a temperature meter of the worlds, the output of which is connected to the first input of the device for stabilizing the level of contrast radiation, the output of which is connected to the actuator of the background emitter, characterized the fact that an additional control device is introduced into it, the output of which is connected to the second input of the device for stabilizing the level of contrast about radiation. 2. The infrared collimator according to claim 1, characterized in that the device for stabilizing the level of contrast radiation contains a processor, the first and second inputs of which are the first and second inputs of the device for stabilizing the level of contrast radiation, a temperature difference meter between the background emitter and the world, the output of which is connected to the third input of the processor, and the output stage, the input of which is connected to the output of the processor, and the output is the output of the device for stabilizing the level of contrast radiation. 3. The infrared collimator according to claim 1, characterized in that the control device is designed as an interface device, the output of which is the output of the control device. 4. The infrared collimator according to claim 1, characterized in that the control device is made in the form of series-connected master and interface device, the output of which is the output of the control device.