RU169583U1 - MICROWAVE RADIOMETER CALIBRATION DEVICE - Google Patents

Abstract

The utility model relates to devices for calibrating microwave radiometer wavelengths and includes an electrically controlled modulator-calibrator placed in a thermostated housing, integrated into the waveguide path of the microwave radiometer between the antenna system and the receiver, supplemented by a system for controlling the time sequence of calibration and effective temperatures of calibration loads, which personal tunable stabilized power supply controlled from a personal computer a computer, and a control module that controls the process of temperature control of the case of the modulator-calibrator, controlled by software using a personal computer. The technical result consists in the ability to carry out calibration with the least loss in accuracy. 1 ill.

Description

The utility model relates to means for calibrating measuring instruments and can be used to calibrate microwave radiometers.

To realize the maximum fluctuation sensitivity of radiometric receivers limited only by white noise, it is necessary to apply measures that exclude the influence of slow variations in the transmission coefficient and the level of intrinsic noise (flicker noise) and having a spectrum of the form 1 / f. The low-frequency noise components of radiometers are associated with technical reasons such as variations in the supply voltage of amplifiers, changes in the temperature of active and passive elements, slow fluctuations in the parameters of electronic components, shot noise of a quadratic detector, etc. To suppress low-frequency noise, the intensity of which is usually much higher than the intensity of white noise, in addition to temperature control and the use of stable power sources, various circuit solutions are used: modulation, correlation, and other radiometric schemes. In the widely used modulation scheme, a quick periodic switching of the receiver input between the antenna and the reference load with a stable temperature is performed. Moreover, the effective noise temperature of the reference load should be close to the antenna temperature of the source under study. Switching the input signal is carried out using a modulator or switch of one type or another. The output signal of the radiometer in this case is the time-averaged voltage difference of the quadratic detector in two positions (phases) of the modulator.

Interpretation of radiometric measurements also requires the establishment of a one-to-one correspondence between the output readings of the radiometric system and the antenna temperature, i.e. calibration. To calibrate the radiometer gain, it is necessary to have a source (or sources) of a reference signal with two intensity levels (for a linear characteristic of power transmission). At the time of registration of the reference calibration signals, the measurement of the investigated signal is interrupted; Thus, the time of its accumulation is reduced and, accordingly, the resulting sensitivity decreases (for a fixed total measurement time). Levels of calibration signals are chosen close to the level of the measured signal. In addition, under these conditions, to minimize the measurement error, the total time spent on calibration should be approximately equal to the accumulation time of the measured signal. To obtain high measurement accuracy, large accumulation times of signals are also required. And in order to exclude the influence of the transfer coefficient drift on the measurement accuracy, calibration should also be done quite often. In this case, the optimal solution is to include calibration in each modulation cycle. Modern digital processing allows registration and averaging of the measured signal and calibration signals in each phase of the modulation-calibration separately. Then, after a sufficiently long averaging over many cycles, recalculate the output signal levels to antenna temperatures.

Known schemes combining modulation and calibration in one cycle. To do this, an antenna, a low-level calibration signal source (cold), a high-level calibration signal source (hot) are connected in series to the receiver input. To implement this principle, as a rule, two different noise sources and several switches are used.

The closest in technical essence to the proposed device is a prototype internal calibration system described in The Ground-Based Scanning Radiometer: A Powerful Tool for Study of the Arctic Atmosphere / Domenico Cimini, Ed R. Westwater, Albin J. Gasiewski, Marian Klein , Vladimir Ye. Leuski, and Sally G. Dowlatshahi // IEEE TRANSACTIONS ON GEOSCIENCE AND REMOTE SENSING, VOL. 45, NO. 9, SEPTEMBER 2007, P. 2759. This system consists of an attenuator (cold load), a p-i-n diode (hot load) and a switch for changing input loads (hot, cold, and signal from the measurement object) built into the measuring circuit of the radiometer.

The disadvantages of the prototype device are, firstly, the use of different devices as cold and hot loads and a key for changing them, which increases time losses and, accordingly, worsens the measurement accuracy, and secondly, the inability to control the times and levels of the calibration signal, which also reduces the accuracy of the measurement.

The objective of the invention is to provide a device that allows the calibration of microwave radiometers with easily tunable parameters of the time sequence and levels of the calibration signal during the measurement itself and thus minimize calibration error, significantly increasing the accuracy of measurements.

The technical effect is achieved by the fact that the device for calibrating the microwave radiometer is integrated in the measuring circuit of the radiometer and combines modulation and calibration in one cycle.

New is that the proposed device includes an electrically controlled modulator-calibrator placed in a thermostated housing, built into the waveguide path of the microwave radiometer between the antenna system and the receiver, supplemented by a control system for the calibration time sequence and effective calibration load temperatures, which is a tunable stabilized power source controlled by a personal computer and regulating the process of temperature control Calibrator whisker modulator control module controlled by software using a personal computer.

The utility model is illustrated in FIG. 1, which illustrates the integration of a calibration device into a radiometric measurement circuit: 1 — a modulator-calibrator, 2 — a waveguide path of a radiometer, 3 — a personal computer, 4 — a tunable stabilized power supply, 5 — a control module.

The proposed device consists of a thermostatically controlled electrically controlled modulator-calibrator 1, built into the waveguide path 2 of the microwave radiometer between the antenna system and the receiver, supplemented by a control system for the timing of calibration and effective temperatures of the calibration loads, which is a tunable stabilized power source 4, controlled from a personal computer 3 as well as placed after the analog-to-digital converter in the radiometer and adjust The process of temperature control of the case of the modulator-calibrator digital control module 5, controlled by software using a personal computer 3.

The main element of the calibration and data acquisition system is a modulator-calibrator 1 placed in a thermostated housing with a temperature sensor and a heater, included in the waveguide path 2 between the radiometer antenna and the receiver.

The electrically controlled modulator-calibrator 1 is a 10 mm waveguide insert that contains a monolithic integrated circuit (MIS) mounted in the E-plane of the waveguide. The MIS, which is mounted in a segment of the slit waveguide line, consists of a series of parallel chains connected in series by GaAs diodes to the Schottky barrier. The use of a distributed chain of diodes in MIS leads to a decrease in the quality factor of the waveguide-slit line and improves matching. External control of the MIS current from a tunable stabilized power supply 4 leads to a controlled change in the transfer coefficient of the modulator-calibrator 1 and obtain highly stable calibration values of the effective temperature in the range from ≈0.6 T ₀ to (2 ÷ 3) T ₀ , where T ₀ is the physical diode temperature. Direct losses in the modulator-calibrator 1 are 0.5-0.7 dB.

To carry out fast periodic calibration of the radiometer, the modulator-calibrator 1 sequentially switches between the three states. At zero control current, the modulator-calibrator 1 is open, and the signal from the antenna is fed to the input of the receiver. When bias current is applied, the antenna input is locked, and the calibration signal emitted by the calibrator-modulator 1 is received at the receiver input. With a low value of the control current (about 2 mA), the calibration signal with an effective temperature of ~ 160-180 K (the so-called cold calibration load). At a control current of 30-50 mA, the antenna input is also closed, and its effective noise temperature is about 300 K (the so-called hot calibration load).

The control system for the calibration time sequence and calibration signal levels is a combination of a personal computer 3 and a tunable stabilized power supply 4. The values of the control currents are set by a personal computer 3 using a tunable stabilized power source 4. An algorithm setting the optimal one based on the personal computer 3 criterion of minimizing the calibration error and maximizing the measurement time of the useful signal of the object calibration times and effective temperatures of calibration signals. The system, by minimizing the calibration error expressed by relation (1), automatically calculates and supplies currents to the modulator-calibrator 1, which determine the effective temperatures of the calibration signals (cold and hot calibration loads), as well as the ratio of the times during which the modulator-calibrator 1 is supplied currents corresponding to these calibration signals. This allows to obtain the smallest measurement error associated with the calibration, and to increase the accuracy of measurements.

Here T _s is the noise temperature of the measuring system, Δν is the width of the ADC spectral channel, t is the total measurement time, τ ₁ , τ ₂ are the calibration times for cold and hot calibration loads, respectively, T ₁ , T ₂ are the effective temperatures of the calibration loads, T _a is the brightness temperature of the radiation of the object.

The output signals of the radiometer receiver are digitized using an analog-to-digital converter and averaged in the control module 5 for each phase of the modulation-calibration separately. After that, the averaged values of the effective temperatures of the calibration loads and the brightness temperature of the radiation from the object are transferred to a personal computer 3, where they are statistically processed for the desired time interval.

In order to maintain constant values of the effective temperatures of the calibration signals, the housing of the modulator-calibrator 1 is thermostatically controlled with an accuracy of 0.2 K. For this, a temperature sensor and a heater are installed on the housing. The temperature value of the housing of the modulator-calibrator 1 and the temperature control process is controlled by software using a personal computer 3 through the control module 5.

The described calibration system is implemented for microwave radiometers and spectroradiometers operating in the wavelength ranges from 8 mm to 2 mm.

Thus, the proposed device for calibration makes it possible to increase the accuracy of measurements made by the radiometer, firstly, through the use of a modulator-calibrator, which, unlike the prototype, combines cold and hot calibration loads and the key function and is electrically controlled, therefore allows you to save time on switching the input of the radiometer between loads and use the freed up time directly for measurements, which increases the accuracy of measurements, and secondly, due to the use of a control system for the time sequence of calibration and effective temperatures of calibration loads, which automatically calculates and sets the measurement times of the signal from the measured object and calibration loads based on the criterion of the best measurement accuracy (minimizing the calibration error and maximizing the measurement time of the signal from the object) and, thirdly, for the use of a control unit that stabilizes the temperature of the modulator-calibrator, and therefore minimizes changes The values of effective temperatures of calibration loads, which minimizes calibration error and increases measurement accuracy.

Claims (1)

A device for calibrating a microwave radiometer, integrated into the measuring circuit of the radiometer, combining modulation and calibration in one cycle, characterized in that it includes an electrically controlled modulator-calibrator placed in a thermostated housing, built into the waveguide path of the microwave radiometer between the antenna system and the receiver, supplemented a system for controlling the time sequence of calibration and effective temperatures of calibration loads, which is a tunable a stabilized power supply controlled from a personal computer, and a control module that controls the process of temperature control of the case of the modulator-calibrator, controlled by software using a personal computer.

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