RU2726276C1 - Ground-based passive microwave radiometric system for measuring altitude profile of temperature of lower and medium atmosphere of earth - Google Patents

Abstract

FIELD: measurement.SUBSTANCE: invention relates to devices for measuring characteristics of atmosphere, enables to measure altitude profile of temperature of lower and middle atmosphere from surface of Earth and is a passive ground complex of three interfaced with personal computer spectroradiometers, each of which has internal calibration system and horn antenna of extremely small dimensions with special shaped section.EFFECT: technical result when implementing disclosed solution is increased mobility and reduced overall dimensions of device.1 cl, 1 dwg

Description

The invention relates to means for determining the characteristics of the atmosphere, namely the altitude temperature profile of the lower and middle atmosphere of the Earth.

To date, the creation of an adequate system for monitoring the state of the environment, providing a correct forecast of its evolution, has become key among the problems covered by Earth sciences. Understanding and solving these problems is impossible without large-scale experiments to study processes in the Earth’s atmosphere.

Currently, the main supplier of experimental data on the state of the lower and middle atmosphere are satellite-based devices that provide sounding and prediction of the state of the atmosphere using a large number of distance-wave devices operating in both active and passive modes in a wide range of wavelengths: from vacuum ultraviolet to millimeter and centimeter. However, the main problem of satellite data is the large scale of averaging over zonal-meridional coordinates, amounting to several hundred (up to 500-700 or more) kilometers and a relatively low time resolution (of the order of 1-2 days).

In particular, the currently existing instruments for measuring the altitude profile of the temperature of the atmosphere either do not provide high spatial-temporal resolution (satellite microwave measurements - resolution of the order of days and hundreds of kilometers horizontally), or use non-mobile equipment (lidar measurements - stationary equipment, previous microwave ground measurements - the mass of the apparatus is of the order of several hundred kg), or cannot be correctly combined with methods for determining other atmospheric characteristics (all of the above).

, О. Microwave radiometer to retrieve temperature profiles from the surface to the stratopause / O.

, A. Murk, N.

, C.

, P. Eriksson // Atmos. Meas. Tech. 2013. V. 6, P. 2477-2494. В данной публикации представлен наземный пассивный радиометрический комплекс, измеряющий спектр собственного излучения атмосферы в 5-миллиметровой полосе поглощения молекулярного кислорода. Данный комплекс состоит из внешней калибровочной системы - двух эталонов - черных тел комнатной температуры и температуры кипения жидкого азота; спектрорадиометра, состоящего из антенной системы, включающей в себя рупорный облучатель и параболическое зеркало, принимающей сигнал из атмосферы; передаточного волноводного тракта от антенной системы к двум супергетеродинным приемникам с разными рабочими диапазонами частот и цифрового анализатора спектра, а также персонального компьютера для обработки данных.The closest in technical essence to the proposed complex is taken as a prototype ground-based passive microwave radiometric complex for measuring the altitude profile of the temperature of the atmosphere, described in the publication

, O. Microwave radiometer to retrieve temperature profiles from the surface to the stratopause / O.

, A. Murk, N.

, C.

, P. Eriksson // Atmos. Meas. Tech. 2013. V. 6, P. 2477-2494. This publication presents a ground-based passive radiometric complex that measures the spectrum of the atmospheric radiation in a 5-mm absorption band of molecular oxygen. This complex consists of an external calibration system - two standards - black bodies at room temperature and the boiling point of liquid nitrogen; a spectroradiometer consisting of an antenna system including a horn irradiator and a parabolic mirror receiving a signal from the atmosphere; transmission waveguide path from the antenna system to two superheterodyne receivers with different operating frequency ranges and a digital spectrum analyzer, as well as a personal computer for data processing.

The disadvantages of the prototype are: firstly, the fact that the calibration system consists of external standards and uses liquid nitrogen, which leads not only to an increase in the dimensions and mass of the measuring system itself, and hence to its low mobility, but also to an increase in cost and time measurements with deterioration of their accuracy; secondly, a bulky antenna system consisting of a parabolic mirror and a standard horn antenna, with which a narrow radiation pattern of the antenna system is achieved, which makes the complex very difficult to move.

The objective of the invention is to create a complex that allows you to measure the altitude profile of the temperature of the lower and middle atmosphere from the surface of the Earth using cheap, small-sized and mobile equipment.

The technical effect is achieved by the fact that the proposed ground-based passive microwave radiometric complex for measuring the altitude temperature profile of the lower and middle atmosphere of the Earth, from at least one spectroradiometer with a calibration system, including an antenna system connected through a waveguide path to a superheterodyne receiver, the output of which is connected to a digital spectrum analyzer configured to interface with a personal computer for data processing

The new one is that the proposed complex consists of three spectroradiometers that are capable of interfacing with a personal computer, taking measurements at different altitude ranges, in total covering the altitude range of the lower and middle Earth’s atmosphere, each of which includes an antenna system in the form of extremely small horn antennas dimensions with a specially shaped cross-section, designed for the range of received frequencies, which is connected by a waveguide path to a superheterodyne receiver, the output of which is connected to a spectrum analyzer, each spectroradiometer has its own internal calibration system, which is a modulator-calibrator built into the waveguide path, controlled by personal computer through the power supply.

The invention is illustrated in FIG. 1, which shows a block diagram of one of the spectroradiometers included in the proposed complex: 1 - antenna system, 2 - waveguide path, 3 - modulator-calibrator, 4 - receiver, 5 - spectrum analyzer, 6 - personal computer, 7 - block nutrition.

The proposed complex includes three spectroradiometers constructed according to the classical superheterodyne scheme for receiving and spectral analysis of millimeter wavelength radiation, which allows you to transfer the spectrum of millimetric intrinsic radiation of the atmosphere to the lower frequency range (from zero to several GHz), in which spectral analysis of the received radiation with the required frequency resolution.

Each of the spectroradiometers (see Fig. 1) consists of an antenna system 1, which is connected to a superheterodyne receiver 4 by a waveguide path 2 with an integrated modulator-calibrator 3, controlled from a personal computer 6 through a power supply 7. The output of the superheterodyne receiver 4 is connected to a spectrum analyzer 5, which is paired with a computer 6.

The antenna system 1 for each of the spectroradiometers is a horn antenna of extremely small dimensions with a specially shaped cross-section, designed for the range of received frequencies, which has a narrow radiation pattern and converts the mode of a rectangular single-mode waveguide into a quasi-Gaussian wave beam with a flat phase front with good efficiency. Such characteristics of the antenna system 1 make it possible to minimize the error of measurements of atmospheric brightness due to scattering. The stabilization of the characteristics of the antenna’s own radiation, due to ohmic losses in the horn, is achieved by placing it in a thermostatically controlled housing. The received signal from the antenna system 1 through the waveguide path 2 enters the superheterodyne receiver 4, and from it to the spectrum analyzer 5 and then to the personal computer 6.

The modulator-calibrator 3, built into the waveguide path 2, is a current-controlled waveguide device with a series of parallel chains of diodes with a Schottky barrier. The magnitude of the control current is set from the personal computer 6 through the power supply 7. At zero bias current, the input and output of the modulator-calibrator 3 are well (with losses better than 0.7 dB) matched with the antenna and receiving sections of waveguide path 2, which ensures the passage of the received antenna system 1 atmospheric thermal radiation in a 5 mm lossless molecular oxygen emission band. When the current is turned on, the modulator-calibrator 3, firstly, locks the input of the superheterodyne receiver 4, attenuating the radiation received by the antenna system 1 by 20-30 dB (depending on the current strength), and secondly, sends its own noise signal to the superheterodyne receiver 4, whose effective radiation temperature, depending on the current value, is set at levels from 150 to 160 K (analogue of the “cold” load in the prototype) or from 350 to 360 K (analogue of the “warm” load in the prototype). The information obtained from the calibration loads is used to determine the absolute value of the brightness temperature of the measured own radiation of the atmosphere.

Three spectroradiometers have the following features.

The spectroradiometer for sensing the surface layer of the atmosphere has a horn antenna tuned to the received frequency range of 55-59 GHz and converts the mode of a rectangular single-mode waveguide into a quasi-Gaussian wave beam with a flat phase front with an efficiency of better than 95%. The antenna beamwidth is 3.8 °.

The spectroradiometer for sensing the free troposphere has a horn antenna tuned to the frequency range of 50-55 GHz and converts the mode of a rectangular single-mode waveguide into a quasi-Gaussian wave beam with a flat phase front with an efficiency better than 98%. The antenna beamwidth is 4.2 °.

The stratosphere sensing spectroradiometer has a horn antenna tuned to the received frequency range of 52.45-54.5 GHz and converts the mode of a rectangular single-mode waveguide into a quasi-Gaussian wave beam with a flat phase front with an efficiency of better than 97%. The antenna beamwidth is 4.1 °.

The use of an internal calibration system and a specially profiled horn antenna in the design of each spectroradiometer made it possible to reduce the dimensions of each spectroradiometer to the dimensions of a small case and to avoid the cost of maintaining a bulky external calibration system. The division into three cases made it possible not only to autonomously measure the temperature characteristics at different levels of the heights of the atmosphere, but also to facilitate the possibility of transportation and deployment of the complex.

The complex is a mobile device for continuous around-the-clock all-weather acquisition of the spectra of the atmospheric radiation in the band 50-60 GHz, which allows you to restore the temperature of the atmosphere in the altitude range 0-55 km.

Claims (1)

A ground-based passive microwave radiometric complex for measuring the altitude profile of the temperature of the lower and middle Earth’s atmosphere from at least one spectroradiometer with a calibration system, including an antenna system connected through a waveguide path to a superheterodyne receiver, the output of which is connected to a digital spectrum analyzer configured to interface with personal computer for data processing, characterized in that it consists of three spectroradiometers that are capable of interfacing with a personal computer, measuring at different altitude ranges, in total covering the altitude range of the lower and middle Earth’s atmosphere, each of which includes an antenna system in the form of a horn antenna extremely small dimensions with a profiled cross section designed for the range of received frequencies, which is connected by a waveguide path to a superheterodyne receiver, the output of which is connected to a spectrum analyzer, each The electroradiometer has its own internal calibration system, which is a modulator-calibrator built into the waveguide path, controlled from a personal computer through a power supply.

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