RU2124705C1 - Method of shf measurement of physical temperature of objects with use of radiometer and device for its implementation - Google Patents

Abstract

FIELD: technique measuring intensity of thermal radio radiation of objects. SUBSTANCE: method of SHF measurement of physical temperature of objects with use of radiometer involves measurements separated in time. Antenna for each measurement is directed to object to form noise signal from object across its output. First auxiliary noise signal is formed first, then second auxiliary noise signal is fed through antenna to object for the time of measurement of its physical temperature. Signal from antenna output and first auxiliary noise signal are fed into first and second inputs of radiometer correspondingly. Level of noise of first and second auxiliary signals is controlled by integrated voltage of radiometer that is measured. Calibration with the aid of exterior calibration sources is conducted once prior to measurements of integrated voltage of radiometer from objects separated in time and its results are stored for long time. Physical temperature of objects is computed by results of measurements of integrated voltage of radiometer with allowance for stored results of calibration. EFFECT: simplified process of measurements of physical temperature of objects separated in time. 8 cl, 5 dwg

Description

 The invention relates to a radio measuring technique, in particular to a technique for measuring the intensity of thermal radio emission of objects, and can be used in medical practice.

 Known radio thermometer [1], which implements a known method for measuring the physical temperature of objects on a microwave [2]. However, the known radio thermometer [1] has a complex structural diagram and is difficult to manufacture and configure.

 Closest to the proposed invention, adopted as a prototype, is a method of measuring the physical temperature of objects on a microwave using a modulation radiometer and a device (radiothermometer) for its implementation [3]. According to the known method [3], after calibration by external calibration sources of the device for implementing the method, an antenna is directed to the object to generate a noise signal from the object at its output, a first auxiliary noise signal is generated, a second auxiliary noise signal is generated and constantly fed through the antenna to the object, the signal from the antenna output and the first auxiliary noise signal is supplied to the first and second inputs of the radiometer, respectively, and the noise levels of the first and second auxiliary signals are are automatically regulated by the integrated output voltage of the radiometer, which is measured and which is proportional to the physical temperature of the object.

 A device for implementing the known method [3] contains (Fig. 1) a controlled noise generator 1 (GS1), a series-connected antenna 2, a directional device 3, a modulation radiometer 4, the output of which is connected to the control input GS1. The GSH1 outputs are connected - the first output through the first adjustable microwave attenuator 5 to the second input of the directional device 3, and the second output through the second adjustable microwave attenuator 6 to the second input of the radiometer 4. The radiometer 4 contains a controllable switch 7, a signal converter 8 ( contains a series-connected receiving device 9 and an integrator 10) and a recorder 11. The inputs of the switch 7 are the first and second inputs of the radiometer 4; the second output of the receiving device 9 is connected to the control input of the switch 7. The output of the radiometer 4 is the output of the integrator 10 connected to the input of the recorder 11.

 The known device (Fig. 1) that implements the known measurement method [3], operates as follows.

Antenna 2, directed toward the object (not shown in Fig. 1), receives radio emission of thermal origin emitted by the object and generates a noise signal in the microwave range at its output. This signal, passing through a three-port directional device 3 (for example, a circulator), in accordance with the known principle of the modulation radiometer [4], periodically, alternately with a low modulation frequency F _о, passes through switch 7 to the input of the receiving device 9. In the receiving device 9 the microwave noise signal is amplified, detected, amplified and synchronously detected at a frequency F _o , supplied to the integrator 10 and supplied to the recorder 11 for registration and to the control input GS1 as a DC voltage U ₁ . Controlled microwave noise signal GSH1 through the attenuator 6 is fed to the second input of the switch 7, which acts as a comparison device in a closed servo system of automatic control (CAP) with negative feedback (nodes 7-10, 1, 6).

The input for the tracking ATS is the signal at the first input of the radiometer 4. With a sufficiently large transmission coefficient of the open ATS, the microwave noise signal at the output of the attenuator 6 (the first auxiliary noise signal) in a closed ATS is almost equal to the input effect. With a linear dependence of the power of the noise signal GSH1 on the control voltage, the voltage of the error signal ATS U _{1 is} proportional to the noise power of the input action. In accordance with the well-known Nyquist formula, the power of a noise signal is also related to its temperature by a proportional dependence. The input power of the ATS is equal to the sum of the powers of the two noise signals. The power of one of them, the radiation signal from the object, is proportional to its brightness temperature T _i = T _f • E, where T _f and E are the physical temperature and emissivity of the object, respectively. Another signal is formed after the signal passes from the output of the attenuator 5 (second auxiliary signal) through the directional device 3 and the antenna 2 to the object, reflection from it and the reflected signal arrives at the first input of the radiometer 4. The attenuators 5 and 6 in the known device are adjusted so that the temperature the reflected part of the second auxiliary noise signal was equal to T _from = T _f R = T _f (1-E), where R is the reflection coefficient (power) of the object when the antenna 2 is directed at it. Then, the input power (and also first and second auxiliary signals) and the voltage of the error signal U ₁ will be proportional to the physical temperature of the object T _f .

In order to bring the voltage U ₁ in accordance with the measured temperature T _f in the known device [3], before measurement, it is calibrated using external calibration sources. This calibration consists in measuring the thermal radiation power of two calibration sources with known temperatures, which correspond to two readings recorded by the recorder 11.

 The known measurement method and device (radiometer) for its implementation have the following disadvantages: the complexity of the measurement process and device, a large measurement error and limited functionality.

 The complexity of the measurement process is caused by the need to conduct multiple calibrations using external calibration sources when performing time-spaced measurements under operating conditions. As the external calibration radiation sources with known temperatures, two thermostated vessels with water are used, which are separated from the radiothermometer antenna by a thin dielectric film [5]. Such an external calibration source is a high-precision device subject to periodic metrological certification in the bodies of Gosstandart and requiring the corresponding highly qualified operator. The cost of such a source is close to the cost of a radiometer. In addition, the on-line calibration using an external source, for example, in a medical institution (in a hospital room, operating room, or clinic’s room), is associated with a number of inconveniences: the need to constantly have an additional device in the workplace that requires careful care, and a large investment of time for calibration operations, the possibility of errors in time pressure conditions, etc.

 If frequent calibration is rejected under operating conditions, the measurement error may increase, in particular, due to changes in the temperature of the antenna and the microwave cable for connecting it to the radiometer. It can be shown that in this case, a change, for example, by 3 degrees C of the temperature of the antenna with the cable, characterized by a total microwave loss of 1 dB, will lead to an increase in the unaccounted error of 0.6 degrees C. In addition, the rejection of frequent calibration limits the functionality of the known measurement method and device for its implementation: there is no possibility of operational verification of the metrological characteristics of the device and the ability to quickly replace one type of antenna with another type of antenna, which differs from the first in its diagnostic capabilities and microwave characteristics.

 The complexity of the known device [3] is also due to complex microwave attenuators in design with mechanical adjustment of attenuation, which reduces the stability of their parameters over time. The need to have GSH1 with two outputs implies the presence of an additional microwave unit - a power divider. The complexity of the design clearly demonstrates the description of a real device [1] for implementing the known method [2, 3].

 The claimed technical solution is aimed at simplifying the process of time-spaced measurements of the physical temperature of objects and the device itself (radiothermometer) for measuring it.

 The essence of the claimed technical solution lies in the fact that, according to the method of measuring the physical temperature of objects on a microwave using a radiometer, including time-separated measurements, according to which, for each measurement, an antenna is directed to the object to form a noise signal from the object at its output, form the first auxiliary a noise signal, during the measurement of the physical temperature, a second auxiliary noise signal, a signal from the antenna output and the first auxiliary signal are brought to the object through the antenna The noise signal is fed to the first and second inputs of the radiometer, respectively, the noise level of the first and second auxiliary signals is controlled by the integrated voltage of the radiometer, which is measured, calibration by external calibration sources is performed once before the time-separated measurements of the integrated voltage of the radiometer from objects, and the results are stored for a long time time, and the physical temperature of objects is calculated from the results of measurements of the integrated voltage of the radiometer and taking into account the memorized calibration results; at the same time, a code switch block, a first resistor connected to a noise generator control input, and a second resistor, a connecting element and a second controlled noise generator are introduced in series into the device for implementing the method, comprising a controlled noise generator and a series-connected antenna, a directional device and a radiometer whose output is connected to the second input of the directional device; the output of the first noise generator is connected to the second input of the radiometer, the first output of which is connected to the inputs of the first and second resistors, and the output of the code switch block is connected to the third input of the radiometer.

 The first particular case of the implementation of the claimed technical solution is aimed at reducing the error of time-spaced measurements of the physical temperature of objects and expanding the functionality.

 The essence of the first particular case of the implementation of the claimed technical solution lies in the fact that according to the claimed technical solution after calibration by external calibration sources, calibration is performed according to the internal calibration source, the results of which are stored and used in calculating the physical temperature of the object.

 The second special case of the implementation of the claimed technical solution, as well as the first special case, is aimed at reducing the error of time-spaced measurements of the physical temperature of objects and expanding the functionality.

 The essence of the second special case lies in the fact that according to the claimed technical solution and in its first special case, immediately after calibration by external calibration sources, the calibration is performed according to the internal source, while the antenna is turned off, it provides a preset reflection from the input of the device that implements the measurement method through it the third and fourth auxiliary noise signals of given levels are brought to its input and the integrated voltage of the radiometer corresponding to the reflected Signals the antenna is reconnected to the input of the device that implements the measurement method, a predetermined reflection from its input is provided, the third and fourth auxiliary noise signals are fed through it to its input, and the integrated voltage of the radiometer corresponding to the reflected signals is measured; the measurement results of the integrated voltage of the radiometer from all four reflected signals are stored for a long time, after which the third and fourth auxiliary signals are turned off; immediately before measuring the integrated voltage of the radiometer from the object, calibration is carried out according to an internal source with an antenna connected, for which a specified reflection from its input is provided, the third and fourth auxiliary noise signals are fed through it to its input, the integrated voltage of the radiometer corresponding to the reflected signals is measured, the measurement results remember at least for the time of measurement of the object, after which the third and fourth auxiliary signals are turned off; at the same time, a DC source with two outputs and a controlled switch, the output of which is connected to the second input of the connecting element made in the form of a controlled switch, are introduced into the device for implementing the claimed technical solution, and the control inputs of the controlled switch and the controlled switch of the connecting element are connected respectively to the first and second additional outputs of the radiometer, the first input of the connecting element is ne the first input of its controlled switch, the output of which is the output of the connecting element, the second input of which is the second input of its controlled switch.

 The third special case of the implementation of the claimed technical solution is aimed at further expanding the functionality.

 The essence of the third special case is that, in the second special case of the implementation of the claimed technical solution, immediately prior to calibration using an internal source with an antenna connected, carried out immediately before measuring the integrated voltage of the radiometer from the object, the antenna is replaced with another.

 The fourth special case of the implementation of the claimed technical solution is aimed at further expanding the functionality.

 The essence of the fourth particular case is that according to the claimed technical solution and its first, second and third special cases, the measurement of the object is carried out by conducting two consecutive measurements of the integrated voltage of the radiometer from the object, according to the results of which, taking into account the results of calibration by external and internal sources, are calculated temperature and emissivity of the object, while in the device for the implementation of the first, second or third particular cases of execution declared Of the technical solution, its connecting element is made in the form of a serial connection of the first and second controlled switches, the control inputs of which are connected respectively to the second and third additional outputs of the radiometer, the second input of the connecting element is the second input of the first controlled switch, the output of which is the output of the connecting element, the first input which is the input of the second controllable switch.

 In FIG. 1 is a structural diagram of a known device for implementing a known method for measuring the physical temperature of an object on a microwave, where 1 is a noise generator, 2 is an antenna, 3 is a directional device, 4 is a modulation radiometer, 5, 6 are adjustable microwave attenuators, 7 is a controlled switch, 8 - signal converter, 9 - receiving device, 10 - integrator, 11 - recorder.

 In FIG. 2 is a structural diagram of the proposed device for implementing the claimed technical solution, where 1 is a noise generator, 2 is an antenna, 3 is a directional device, 4 is a modulation radiometer, 5 is a controllable switch, 6 is a signal converter, 7 is a receiving device, 8 is an integrator , 9 - recorder, 10 - block of code switches, 11, 12 - resistors, 13 - connecting element, 14 - noise generator.

 In FIG. 3 presents a structural diagram of the proposed device for the implementation of the first, second and third particular cases of the implementation of the claimed technical solution, where the numbers 1-14 indicate the same nodes as in FIG. 2, 15 - direct current source, 16 - controlled switch.

 In FIG. 4 presents a structural diagram of the proposed device for the implementation of the fourth particular case of the implementation of the claimed technical solution, where the numbers 1-16 denote the same nodes as in FIG. 3, 17, 18 - controlled switches.

 In FIG. 5 is a structural diagram of the registrar of the proposed devices, where 19 is an analog-to-digital converter with its control circuit, 20 is a programmable input / output port, 21 is a central processor unit with a buffer address register, 22 is a read-only memory device, 23 is a random access memory device 24 - node for the formation of digital indications, 25 - digital indicator, 26 - node push-button control of the device, 27 - decoder code switches with a buffer register for data storage.

 The proposed device for implementing the claimed technical solution contains (Fig. 2) a controlled noise generator 1 (GS1) and a series-connected antenna 2, a directional device 3 and a radiometer 4 (for example, modulation). In the same way as in the prototype device, the radiometer 4 contains a serially connected controlled switch 5, a signal converter 6 (contains a receiver 7 and an integrator 8 connected in series) and a recorder 9. The inputs of the switch 5 are the first and second inputs of the radiometer 4, the third input of which is the second input of the recorder 9. In addition, the block 10 of the code switches, the first resistor 11 connected to the control input GSH1, and the second p The resistor 12, the connecting element 13 and the second controlled noise generator 14 (GS 14), the output of which is connected to the second input of the directional device 3. The output of GS1 is connected to the second input of the radiometer 4, the first output of which is the output of the integrator 8 and the first input of the recorder 9, connected to the inputs of the first and second resistors 11, 12. The output of the code switch block 10 is connected to the third input of the radiometer 4 (to the second input of the recorder 9).

Units and units of the device (radiothermometer) (Fig. 2), such as antenna 2, directional device 3 (for example, a ferrite circulator), nodes of the radiometer 4: switch 5 (made, for example, on pin diodes), receiving device 7 (including nodes of microwave amplification and detection, generation of meander pulses with a modulation frequency F _о , amplification and synchronous filtering and detection at a frequency F _о and other auxiliary nodes) and integrator 8 (made, for example, using an operational amplifier) performed exactly the same as in prototype. Therefore, the possibility of their implementation is not in doubt.

 GSh1, GSh14 can be performed, as in the prototype, on an avalanche-span diode (LPD), the noise power of which is linearly related to the control voltage. The radiothermometer can be further simplified by the use of GSh1, GSh14 in the form of a miniature current-heated resistor, one of which (GSh14) simultaneously performs the function of load resistance for the second input of the directional device 3.

 Block 10 is a set of mechanical code switches for electrical signals used in radio measurement technology. Resistors 11, 12 can be, for example, resistors C2-29. The connecting element 13 can serve as a simple connection of the resistor 12 with the resistor GSh14.

The registrar 9 can be built on the basis of elements, microcircuits and large integrated circuits (LSI) of digital and computer technology. In FIG. 5 is a structural diagram of one of the possible embodiments of the recorder 9 in the proposed radiometer. It contains an analog-to-digital converter 19 (ADC 19) with its control circuit, a programmable digital information input / output port 20, a central processor unit 21 with a buffer address register to separate the address and data bus (in the case of using a microprocessor of type 8085, which has 8 the least significant bits of the address coincide with 8 bits of the data bus) and a decoder for controlling and selecting memory, read-only memory 22 (ROM 22) for storing software, random access memory 23 (RAM 23) for operating full support of the software, as well as for storing the results of measurements and calculations, the node 24 for the formation of digital indications with a digital indicator 25, the node 26 of the push-button control of the radiometer and the decoder 27 of the code switches with a buffer register for data storage. The first input of the recorder is the input of the ADC 19; additional outputs of the recorder 9 are the outputs of the programmable port 20, and the second input of the registrar 9 (data bus from block 10 with a conductor for the polling signal) is the inputs / outputs of the code switch decoder 27. The registrar 9 provides the following functionality of the radiometer:
- management of calibration and measurement processes,
- analog-to-digital conversion of the measuring signals, storing them in RAM, calculating the physical temperature and emissivity of the object,
- output of the calculation results to a digital indicator and storing them in RAM,
- transfer of an array of accumulated data to an external computer (if necessary).

In the absence of measured signals from the object (not shown in Fig. 2), the voltage U ₁ at the output of the integrator 8 is zero, and GS1, GS14 have noise power levels corresponding to a constant temperature T _{p of the} input part of the radiometer (nodes 1, 3, 5, 14 ) The input part of the radiometer, as is customary in modern high-precision radiometers, is placed in the thermostat along with the sensitive and actuating elements of the thermal stabilization system (not shown in Fig. 2). The amplifier of this system is usually located in the radiometer 4 (also not shown in Fig. 2).

 Radiometer for the implementation of the proposed technical solution works as follows.

When the antenna 2 is directed towards the object, it receives radio emission of thermal origin from the object and generates a noise signal in the microwave range at its output. This signal, having passed through the device 3, in accordance with the known principle of the modulation radiometer [4], periodically, alternately with a low modulation frequency F _о, passes through the switch 5 to the input of the device 7. In the device 7, the microwave noise signal is amplified, detected, then amplified, filtered (synchronously) and detected (synchronously) at a frequency Fo, enters the integrator 8 and is supplied as a DC voltage U ₁ to the recorder 9 and through the resistor 11 to the control input GS1. A controlled microwave noise signal from the output of GSH1 is fed to the second input of switch 5, which acts as a comparison device in a closed servo system of automatic control (CAP) with negative feedback (nodes 5-8, 11, 1). The input for the tracking ATS is the signal at the first input of the radiometer 4. With a sufficiently large transmission coefficient of the open ATS, the microwave noise signal at the output of GS1 (the first auxiliary noise signal) in a closed system is almost equal to the input effect. The noise temperatures of these signals are also almost equal to each other, since, in accordance with the well-known Nyquist formula, the power of a noise signal is related to its temperature by a proportional dependence. The input power of the ATS for the time of calibration using external sources and measuring the physical temperature is equal to the sum of the powers of two noise signals. The power of one of them, the radiation signal from the object, is proportional to its brightness temperature T _i = T _f E, where T _f and E are the physical temperature and emissivity of the object, respectively. To create a second noise signal during calibration by external sources and measure the physical temperature, a second auxiliary noise signal with a temperature almost equal to the physical temperature of the object T _{f is} supplied to the object and through the antenna 2. In the proposed radiometer, this is as follows.

The voltage of the error signal U ₁ through the resistor 12, the connecting element 13 is supplied to the input GSH14, structurally identical to GS1. By selecting the value of resistor 12 relative to the value of resistor 11, in the manufacture of the radiothermometer, such noise power is achieved at the output of GSh14 that, taking into account the possible electrical non-identity of GSh1 and GSh14, in terms of noise level and noise signal loss when passing from GSh14 output through device 3 and antenna 2 to the second object the auxiliary noise signal had a temperature almost equal to the physical temperature of the object T _f . With a sufficiently large transfer coefficient in a closed ATS, this selection of power levels GS1 and GS14 is not violated when the measured physical temperature of the object changes. In this case, the temperature of the reflected part of the second auxiliary noise signal will be equal to T _from = T _f R = T _f (1-E), where R is the reflection coefficient (in power) of the object when the antenna 2 is directed at it. Then, the input power (a also the power of the first and second auxiliary signals) will be proportional to the physical temperature of the object T _f . In accordance with the theory of servo ATS with a sufficiently large transmission coefficient between the measured temperature difference (T _f -T _p ) and the square of the voltage of the error signal U ₁ (for the main voltage in the form of a current-heated resistor) or voltage U ₁ (for the linear voltage with linear dependence) proportional dependence is practically fulfilled.

значение T_ф высвечивают на индикаторе 25.By the method of the claimed technical solution, the radiometer is calibrated using two external calibration sources with predetermined temperatures T ₁ and T ₂ , with T _p <T ₁ <T ₂ . After warming up the radiometer and establishing the temperature of its inlet part T _{p, the} antenna 2 is directed to a source with a temperature T ₁ . The measurement result of its radio emission is obtained in the form of the voltage at the output of the ADC 19 (Fig. 5), which differs from the voltage U ₁ only by a scale factor. This voltage in the recorder 9 is squared (hereinafter referred to as GS with a quadratic dependence of the noise power on the control voltage) and is displayed on the indicator 25 as a value of Q ₁ (Fig. 5). Then the antenna 2 is directed to a source with a temperature T ₂ , its radio emission is measured and the square of the measurement result in the form of Q ₂ values is also displayed on the digital indicator 25. The values of T ₁ , T ₂ , Q ₁ , Q _{2 are} stored for a long time by setting in the appropriate the positions of the four code switches of unit 10. Calibration operations using external calibration sources are performed once during the production of the radiothermometer and are repeated during repeated calibrations through the verification interval (at least one year) only s cases. To measure the unknown physical temperature T _{f the} antenna 2 is directed to the object, its radio emission is measured, the square of the measurement result is obtained in the form of the value Q _f and after calculation in the recorder 9 according to the formula

the value of T _f highlight on the indicator 25.

 Simplification of the measurement process according to the proposed technical solution (method) and simplification of the design of the radiometer for their implementation is achieved due to the following. There is no need for on-line calibration using an external calibration source - a high-precision instrument subject to periodic metrological certification in the bodies of Gosstandart and requiring highly qualified operator. At the same time, there was no need to include an external calibration source in the set of the radiometer, the cost of which is close to the cost of the radiometer. There is no need to use complex, labor-consuming microwave components in a radiothermometer: a power divider, adjustable attenuators, which, when placed in a thermostat in order to obtain high accuracy, would further complicate the design.

 The proposed device for the implementation of the first, second or third special cases of the implementation of the claimed technical solution contains (Fig. 3) a device for implementing the claimed technical solution (Fig. 2), which is additionally introduced in series with a DC source 15 with two outputs and a controlled switch 16 the output of which is connected to the second input of the connecting element 13, made in the form of a controlled switch, and the control inputs of the controlled switch 16 and control the removable switch of the connecting element 13 are connected respectively to the first and second additional outputs of the radiometer 4, the first input of the connecting element 13 is the first input of its controlled switch, the output of which is the output of the connecting element 13, the second input of which is the second input of its controlled switch.

 Source 15 can be made on the basis of standard DC stabilizers with an instability of not more than 0.2%.

 The switches 16, 13 can be performed using electrically controlled relays, for example, type RES 79.

The proposed radiothermometer (Fig. 3) works as follows. In the position of the switch of the element 13 "1" (set by the control signal from the recorder 9), its operation does not differ from the operation of the radiometer, performed according to the scheme of FIG. 2. In the position of the switch element 13 "3" according to the method of the first particular case of the implementation of the claimed technical solution after calibration by external calibration sources, the calibration is performed according to the internal calibration source. Using switch 16 to the control input GSH14 from the source 15 the specified lower E _n or upper E are supplied _{to the} levels to form the third and fourth auxiliary noise signals, respectively, at the output of GSH14. These signals, after passing them to the input of the radiometer and reflecting from it, are measured, the measurement results are stored and used in calculating the physical temperature of the object.

In this case, various measurement options are possible, including the methods of the second and third particular cases of the implementation of the claimed technical solution. According to the method of the second frequency case, immediately after calibration by external calibration sources, under the same environmental conditions, the calibration is performed on the internal source, while the antenna 2 is disconnected from the input of the device 3 and provide, for example, complete reflection (idle or short circuit) from the input of the device 3. Through the device 3, the third and fourth auxiliary noise signals, the levels of which are set so that the corresponding reflected signals would be close to each other, are alternately fed to its input Significantly measured signals from external calibration sources with temperatures T ₁ and T ₂ . The squares of the measurement results of the reflected third and fourth auxiliary signals are displayed on the indicator 25 in the form of values of Q ₃ , Q ₄ and using block 10 is stored for a long time. Antenna 2 is reconnected to the input of device 3, for example, it is completely reflected from its input, calibration is performed using the third and fourth auxiliary signals, the squares of the results of which are displayed on indicator 25 in the form of values of Q ₅ , Q ₆ and, using block 10, also remembered for a long time.

где

Значение T_ф высвечивают на индикаторе 25.The above operations are performed in the manufacturing process of the radiometer. During its operation, immediately before measuring the integrated voltage of the radiometer U ₁ from the object, a calibration is performed with the antenna connected and a predetermined reflection from its input (for example, full reflection) using the third and fourth auxiliary noise signals, the squares of the calibration results are displayed on indicator 25 in the form of Q values ₇ , Q ₈ and with the help of RAM 23 is stored at least for the time of measurement of the object, after which the third and fourth auxiliary signals are turned off. After taking measurements of the object, obtaining the values of Q _f calculated in the logger 9 values of T _f by the formula

Where

The value of T _f highlight on the indicator 25.

According to the method of the third particular case of the implementation of the claimed technical solution when operating a radiothermometer, immediately before the measurements of the object, the first antenna (for which calibrations were carried out using external calibration sources and an internal source during the production of the radiometer) is replaced with another one having other diagnostic capabilities. Another antenna may differ from the first one due to microwave losses. In addition, the ambient temperature during the production of the radiometer and during its operation may vary. Therefore, after replacing the antenna with another one, it provides, for example, full reflection from its input, and before measuring the object, calibration is performed using the third and fourth auxiliary noise signals, storing the calibration results in the form of Q ₇ and Q ₈ values, as described above. After taking measurements of the object, obtaining the value of Q _f using the formula (2) calculate and highlight on the indicator 25 the value of T _f .

 The reduction of the measurement error in the proposed measurement methods and the radiometer for their implementation is achieved by taking into account changes in ambient temperature and power losses of the antenna and the connecting cable during operation, the noise contribution of which is indistinguishable from the contribution of the noise radiation of the object. The expansion of functionality is achieved due to the possibility of operational monitoring during operation of the radiometer of its metrological characteristics using an autonomously controlled second generator with calibration noise levels. With its help, it is also possible to control the correct functioning of the main analog systems for compensating the measurement error that occurs when the antenna mismatches with the measurement objects. Additionally, in the third particular case of the claimed technical solution, the functionality is expanded due to the possibility of measurement using antennas with other functionality. At the same time, calibration by external calibration sources is not required.

 The proposed device for the implementation of the fourth particular case of the implementation of the claimed technical solution contains (Fig. 4) a device for implementing the claimed technical solution (Fig. 3), in which its connecting element is made in the form of a serial connection of the first and second controlled switches 17 and 18, control inputs which are connected respectively to the second and third additional outputs of the radiometer 4, the second input of the connecting element 13 is the second input of the first controlled switch STUDIO 17, whose output is the output connector 13, a first input of which is the input of the second controlled switch 18.

 The proposed radiothermometer (Fig. 4) works as follows. In the position of the switches 17 and 18 of the element 13 "1" (set by the control signal from the recorder 9), its operation does not differ from the operation of the radiothermometer performed according to the scheme of FIG. 2. If the signals 18 set the switch 18 to the "1" position and the switch 17 to the "3" position, the internal calibration operations can be performed in the proposed radiothermometer (Fig. 4) in the same way as in the radiometer performed according to the circuit of FIG. 3.

где

значения T_ф и E высвечивают на индикаторе 25 (фиг. 5).To measure unknown physical temperature T _f and emissivity of the object E in the fourth particular case of the implementation of the claimed technical solution, first set the switches 17 and 18 to position "1" and conduct the first measurement of the object. After the first measurement, the switch 18 (Fig. 4) is set to position 3 and the second auxiliary signal is turned off. A second measurement is performed, a square of its result is obtained in the form of a Q _i value proportional to the temperature difference (T _i - T _p ), and after calculating the values of T _f and T _i according to formula (1) and according to the formula

Where

the values of T _f and E are displayed on the indicator 25 (Fig. 5).

 If in the circuit of FIG. 2, the connecting element 13 is made in the form of a controlled switch (as in the scheme of Fig. 3), then in such a radiometer (Fig. 2) it is also possible to carry out the fourth particular case of the implementation of the claimed technical solution.

 The expansion of functionality is achieved by measuring an additional characteristic - the emissivity of the object.

 Detailed documentation has been developed for the proposed radiothermometers. Their samples were made and tested with the participation of representatives of Gosstandart. The test results are positive.

 Literature.

 1. Ostrrieder S., Schaller G. Ein Mikrowellen-Radiometer fur medizinische Anwendungen "Frequenz" 37 (1983). N1, S.7-12.

 2. Ludeke K., Kohler I., Kanzenbach I.:A new radiation - balance microwave thermograph for simultaneous and independent temperature and emissivity measurement. Journal of Microwave Power, 14 (1979), 2, p. 117 = 121.

 3. Ludeke K., Schiek B., Konler I., Method And Arrangement For Measuring The Physical Temperature Of An Object By Means Of Microwaves. United States Patent, N4,235,107; Nov 25, 1980.

 4. Esepkina N.A. and others. Radio telescopes and radiometers. M. Science, 1973

 5. Troitsky V. S. et al. "Method for measuring human body temperature with a decimeter radiothermometer." Medical Technology, 1984, N3, pp. 5-6.

Claims (8)

1. A method of measuring the physical temperature of objects at microwave frequencies using a radiometer, including calibration according to external calibration sources and time-separated measurements, in which for each measurement an antenna is directed to the object to generate a noise signal from the object at its output, the first auxiliary noise signal is generated , at the time of measuring the physical temperature, they form and through the antenna conduct to the object a second auxiliary noise signal, the signal from the output of the antenna and the first auxiliary The first noise signal is conducted to the first and second inputs of the radiometer, respectively, the noise level of the first and second auxiliary signals is regulated by the integrated voltage of the radiometer, which is measured, and the physical temperature of the objects is calculated from the measurement results of the integrated voltage of the radiometer, taking into account the calibration results, characterized in that for the calibration time external sources form a second auxiliary noise signal with a temperature practically equal to the physical temperature of the object T _f , and the calibration is carried out according to two external calibration sources with predetermined temperatures T ₁ and T ₂ , where T _p <T ₁ <T ₂ , where T _p is the temperature of the input part of the radiothermometer, the results of calibration by external calibration sources are stored and stored for Intertesting time interval.  2. The method according to claim 1, characterized in that after calibration by external calibration sources, calibration is performed according to the internal calibration source, the results of which are stored and used in calculating the physical temperature of the object.  3. The method according to claim 1 or 2, characterized in that immediately after the calibration by external calibration sources, the calibration is performed according to the internal source, the antenna is turned off, a predetermined reflection is provided from the input of the device that implements the measurement method, through it to its input the third and fourth auxiliary noise signals of predetermined levels and measure the integrated voltage of the radiometer corresponding to the reflected signals to the input of the device that implements the measurement method, reconnected they read the antenna, provide a predetermined reflection from its input, the third and fourth auxiliary noise signals are passed through it to its input, and the integrated radiometer voltages corresponding to the reflected signals are measured, the measurement results of the integrated radiometer voltages from all four reflected signals are stored and stored during the inter-verification time interval , after which the third and fourth auxiliary signals are turned off, immediately before measuring the integrated voltage by the radio Meters from the object are calibrated against an internal source with an antenna connected, for which they provide a predetermined reflection from its input, the third and fourth auxiliary noise signals are fed through it to its input, the integrated radiometer voltages corresponding to the reflected signals are measured, the measurement results are stored at least for the measurement time of the object, after which the third and fourth auxiliary signals are turned off.  4. The method according to p. 3, characterized in that immediately before the calibration according to the internal source with the antenna connected, carried out immediately before the measurement of the integrated voltage of the radiometer from the object, the antenna is replaced by another.  5. The method according to claims 1, 2, 3 or 4, characterized in that the measurement of the object is carried out by conducting two consecutive measurements of the integrated voltage of the radiometer from the object, according to the results of which, taking into account the result of calibration by external and internal sources, the physical temperature and radiative ability of an object.  6. A device for implementing a method of measuring the physical temperature of objects at microwave frequencies using a radiometer, comprising a controlled noise generator and a series-connected antenna, a directional device and a radiometer containing a recorder, characterized in that a block of code switches, a first resistor connected to the control input of the noise generator, and the second resistor, the connecting element and the second controlled noise generator, the output of which is connected in series a second directional input device, the first noise generator input connected to the second input of the radiometer, whose first output is connected to inputs of the first and second resistors, and the output of the block code switch connected to the third input of the radiometer.  7. The device according to claim 6, characterized in that a DC source with two outputs and a controllable switch, the output of which is connected to the second input of the connecting element, made in the form of a controllable switch, the control inputs of a controllable switch and a controllable switch, are introduced into it the connecting element is connected respectively to the first and second additional outputs of the radiometer, the first input of the connecting element is the first input of its controllably a switch whose output is an output coupling member, the second input of which is the second input of its managed switch.  8. The device according to claim 6, characterized in that it is connected in series with a constant current source with two outputs and a controlled switch, the output of which is connected to the second input of the connecting element, made in the form of a serial connection of the first and second controlled switches, the control inputs controlled switch and the first and second controlled switches of the connecting element are connected respectively to the first, second and third additional outputs of the radiometer, Torah input coupling element is the second input of the first controlled switch, whose output is an output coupling member, the first input of which is the input of the second controlled switch.

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