RU2305305C2 - Ir collimator set - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: IR collimator set has objective, removable test object disposed in focal plane of objective and provided with actuating member, control unit which has output connected with actuating member of background radiator, temperature processor which has output connected with input of control unit, unit for measuring temperature of test object which has output connected with first input of temperature processor, device for measuring temperature difference between background radiator and test object, which has output connected with second input of temperature processor. Environment temperature measuring unit is introduced into device additionally, which unit has output connected to third input of temperature processor. Temperature processor controls value of power voltage of background radiator's actuating member by means of control unit in such a manner than factual value of temperature difference between background radiator and test object coincide with current resulting required value, defined depending on required level of contrast radiation, current temperature of test object and current value of environment temperature to give precision which provides sustain of required level of contrast radiation with admissible error.

EFFECT: improved precision of sustain of contrast radiation level.

1 dwg

Description

The present invention relates to optical instrumentation and is intended to control and measure the parameters of thermal imaging devices (TVP).

Known infrared collimator complex (see Lloyd D. Thermal imaging systems. M., 1978, p. 392, 393), containing a lens, interchangeable to the world, placed in the focal plane of the lens in front of a background emitter equipped with an actuator (heater), a device control (maintaining the temperature difference), the output of which is connected to the Executive element of the background emitter.

The disadvantage of this infrared measuring complex is that maintaining the temperature difference between the background emitter and the world does not maintain the level of contrast radiation when working in a wide range of ambient temperatures, because the level of contrast radiation depends not only on the temperature difference between the background emitter and the world, but also largely on the absolute temperature of the worlds (ambient temperature).

The closest to the proposed invention in terms of technical nature and the achieved effect is an infrared collimator complex (RF Patent No. 2244950, G02B 27/30, published January 20, 2005) containing a lens interchangeable to the world located in the focal plane of the lens, a background emitter located beyond the world and equipped with an actuator, a control device, the output of which is connected to the actuator of the background emitter, a thermal processor, the output of which is connected to the input of the control device, worlds in temperature measurement, the output of which is connected to a first input of a processor temperature, temperature difference measuring device between the base and emitter Mira, whose output is connected to the second input of the temperature of the processor.

Such an infrared collimator complex, when the worlds temperature changes, automatically changes the temperature difference between the background emitter and the world according to the law obtained by calibrating the infrared measuring complex in the working range of ambient temperatures and providing high accuracy of maintaining the level of contrast radiation at any temperature value (within the working range) the environment.

The lack of ideology of such an infrared collimator complex manifests itself during its operation for a long time, when the worlds gradually heat up (cool down) due to the transfer of heat (cold) to it from the background emitter located next to it at a small distance and a temperature difference arises between the world and the environment . (At the beginning of the work, the temperatures of the worlds and the environment practically coincide).

At the same temperatures of the background emitter and the worlds, but different values of the ambient temperature, the level of contrast radiation at the output of the infrared collimator complex will be different.

This happens because the degree of blackness of the surface of the background emitter and the worlds in practice is always less than 1 (usually within 0.92 ... 0.94), and the infrared radiation flux of each of them will be determined not only by their own temperature, but also the temperature of surfaces, the flow of infrared radiation from which is reflected respectively from the background emitter and the worlds.

The world reflects (partially, in accordance with the degree of blackness of its surface) the radiation flux incident on it from the structural elements of the collimator (mainly from the collimator body) having an ambient temperature. Therefore, the radiation flux from the worlds in the case when the ambient temperature is lower than the temperature of the worlds will be less than in the case when the ambient temperature and the temperature of the worlds are the same.

The flow of infrared radiation from the background emitter at different ambient temperatures, but at the same temperature, the worlds will be almost the same, because the background emitter is located at a short distance directly behind the world and is almost completely closed by it. Therefore, it reflects (partially, in accordance with the degree of blackness of its surface) the flow of infrared radiation from the worlds (its back side), which at the same temperatures the worlds will be almost the same.

Thus, at equal temperatures of the worlds and the background emitter, but different ambient temperatures, the level of contrast radiation at the output of the infrared collimator complex, determined by the difference in the infrared fluxes of radiation from the background emitter and the worlds, will be different, i.e. an error occurs in maintaining the level of contrast radiation. Moreover, the magnitude of the error depends not only on the temperature difference between the worlds and the environment, but also on the absolute value of these temperatures (the error is greater at large absolute temperature values).

So, at an ambient temperature of 300 K and a temperature difference between the worlds and the environment of 0.4 K, a change in the level of contrast radiation compared with the case when this difference is 0 K will be of the order of (0.02 ... 0.04) K, that for infrared collimator complexes with an acceptable error, as a rule, no more than ± 0.01 K is unacceptable.

To ensure the required measurement accuracy and maintain the level of contrast radiation, it is necessary to correct the operation of the infrared collimator complex according to the temperature difference between the worlds and the environment, taking into account the absolute value of the ambient temperature.

The aim of the invention is to increase the accuracy of maintaining the level of contrast radiation.

This goal is achieved by the fact that in the infrared collimator complex containing a lens interchangeable with the world, located in the focal plane of the lens, a background emitter located behind the world and equipped with an actuator, a control device whose output is connected to the actuator of the background emitter, a temperature processor, output which is connected to the input of the control device, a device for measuring the temperature of the worlds, the output of which is connected to the first input of the temperature processor, the device from measuring the temperature difference between the background emitter and the world, the output of which is connected to the second input of the temperature processor, an additional device for measuring the ambient temperature is introduced, the output of which is connected to the third input of the temperature processor, while the temperature processor and control device are designed so that the temperature processor by means of a control device, it controls the magnitude of the supply voltage of the executive element of the background emitter so that the actual value times temperature between the background emitter and the world coincides with the current resulting required value, determined depending on the required level of contrast radiation, the current world temperature and the current ambient temperature, with accuracy that maintains the required level of contrast radiation with an allowable error.

The drawing shows a functional diagram of an infrared collimator complex.

The infrared collimator complex contains a lens 1, interchangeable to the world 2, located in the focal plane of the lens 1, a background emitter 3, located behind the replaceable world 2 and provided with an actuating element 4, a control device 5, the output of which is connected to the actuating element 4 of the background emitter 3, a temperature processor 6, the output of which is connected to the input of the control device 5, the device 7 for measuring the temperature of the worlds 2, the output of which is connected to the first input of the processor temperature 6, the device 8 for measuring the difference and temperatures between the background emitter 3 and the world 2, the output of which is connected to the second input of the temperature processor 6, an ambient temperature measuring device 9, the output of which is connected to the third input of the temperature processor 6. The studied thermal imaging device 10 is also shown in the drawing.

The infrared collimator complex operates as follows.

Areas in the central part of the working surface of the background emitter 3 that are not covered by the interchangeable world 2 (which can be, for example, an opaque plate, in the central part of which there are a number of through slots parallel to each other, the width of which and the interval between them are equal for each of the interchangeable the world has its own size, see view A) located in the focal plane of the lens 1, create due to a certain heating of the background emitter 3 and the fact that the world 2 has a temperature different from the temperature of the background emitter 3 The infrared radiation stream (with a certain level of contrast radiation), which is formed by the lens 1 and enters the entrance pupil of the studied thermal imaging device 10 as a contrast collimated infrared radiation stream. In the thermal imaging device 10, the contrast infrared radiation is converted into brightness contrast in the visible spectral region, value which is proportional to the level of contrast radiation.

To reach the required level of contrast radiation and maintain it, the temperature processor 6, from the signal arriving at its first input from the temperature measurement device 7 of the worlds 2, periodically determines the current value of the temperature of the worlds 2 (it is for a certain (short) time after turning on the infrared collimator complex with sufficient accuracy coincides with the ambient temperature). According to the required level of contrast radiation specified by the operator (using the keyboard of the processor of temperature 6) and the measured current value of the temperature of worlds 2, the processor is temperature 6, using the dependences of the level of contrast radiation on the temperature difference between the background emitter 3 and world 2 and the temperature of the world 2 obtained during calibration of the infrared collimator complex, periodically calculates the corresponding current initial required value of the temperature difference between the background emitter 3 and world 2. But, because calibration is carried out in a mode where the temperature of worlds 2 is practically equal to the ambient temperature (i.e., without a long exposure time for each measurement), maintaining the temperature difference between the background emitter 3 and world 2 at a level equal to the current initial required level will ensure the maintenance of the required level contrast radiation only if the temperatures of worlds 2 and the environment are equal.

To maintain the required level of contrast radiation during long-term operation, it is necessary to periodically adjust the temperature difference between the background emitter 3 and the world 2. during operation. This is carried out as follows.

The temperature processor 6 on the signal received at its third input from the device 9 for measuring the ambient temperature determines the current ambient temperature and calculates the current temperature difference between the worlds 2 and the environment. Then, according to the temperature 6 previously incorporated into the processor, the dependences of the correcting offset of the temperature difference between the background emitter 3 and the world 2 (the offset providing compensation for the effect of the temperature difference between the worlds 2 and the environment) on the temperature difference between the worlds 2 and the environment and the absolute value of the ambient temperature environment, the temperature processor 6 periodically calculates the current value of the necessary corrective bias corresponding to the current temperature difference between worlds 2 and the ambient food at the current ambient temperature. (The dependence of the correction bias on the temperature difference between Worlds 2 and the environment and on the absolute value of the ambient temperature is determined by calculation or empirically, separately for each of the interchangeable worlds, because the optical characteristics of the interchangeable worlds (for example, the degree of blackness) can be different. The choice of the desired dependence is carried out by the temperature processor 6 automatically by the number of the interchangeable worlds set by him in the working position (at the command of the operator).

Next, the temperature processor 6 calculates the current resulting required value of the temperature difference between the background radiator 3 and the world 2 as the sum of the current initial required value of the temperature difference between the background radiator 3 and the world 2 and the current correction bias.

This current resultant required value is compared by the temperature processor 6 with the actual value of the temperature difference between the background radiator 3 and the world 2, which it determines by the signal received at its second input from the device 8 for measuring the temperature difference between the background radiator 3 and the world 2.

The temperature processor 6 regulates, using the control device 5, the supply voltage of the actuating element 4 of the background emitter 3 so that the current resulting required and actual values of the temperature difference between the background emitter 3 and the world 2 coincide with an accuracy that ensures the maintenance of the level of contrast radiation at the output of the infrared collimator complex with an error not exceeding the permissible value regardless of the duration of the complex’s operation.

Claims (1)

An infrared collimator complex containing a lens interchangeable with the world located in the focal plane of the lens, a background emitter located behind the world and equipped with an actuator, a control device whose output is connected to the actuator of the background radiator, a temperature processor, the output of which is connected to the input of the control device, a device for measuring the temperature of the worlds, the output of which is connected to the first input of the temperature processor, a device for measuring the temperature difference between a radiator and a world whose output is connected to the second input of the temperature processor, characterized in that an additional device for measuring the ambient temperature is inserted into it, the output of which is connected to the third input of the temperature processor, while the temperature processor and the control device are designed so that the processor temperature control device controls the magnitude of the supply voltage of the Executive element of the background emitter so that the actual value of the difference The temperature between the background emitter and the world coincides with the current resulting required value, determined depending on the required level of contrast radiation, the current world temperature and the current ambient temperature, with accuracy that maintains the required level of contrast radiation with an acceptable error.