RU183716U1 - Lidar for remote measurement of atmospheric temperature - Google Patents

Abstract

The invention relates to the field of measurement technology and relates to a lidar for remote measurement of atmospheric temperature. The lidar includes a laser radiation source, at the output of which there is a transmitting optical system that sends laser radiation to the atmosphere, a receiving telescope, the output of which through an optical scrambler is connected to the input of a double polychromator, which selects the corresponding optical signals of a purely rotational Raman spectrum. The output of the polychromator through monofilament fibers is optically connected to the input of photoelectronic multipliers (PMTs), which convert the optical signals into electrical ones, the output of which is connected to the data processing unit for calculating the temperature. A double polychromator isolates the fourth and twelfth lines of the Stokes and anti-Stokes bands of the purely rotational Raman spectrum of nitrogen molecules. The technical result consists in increasing the steepness of temperature sensitivity and reducing the signal accumulation time. 1 ill.

Description

The utility model relates to measuring equipment and is intended for remote measurement of the temperature of the atmosphere, and can be used at weather stations and other atmospheric monitoring systems.

A device for measuring temperature is known [RF patent No. 129229, 2013]. The disadvantage of this device is the fundamental lack of the ability to conduct remote temperature measurements.

Also known is an aerological radiosonde [RF patent No. 589845, 2006], comprising a temperature sensor and a radio transmitter with which temperature information received as the radiosonde climbs is transmitted to a ground tracking station. The relatively high cost of a one-time measuring module of the radiosonde during regular measurements determines the high cost of operating such a system. Another disadvantage of the radiosonde system is the uncontrollability of the elevation path of the radiosonde. At average statistical speeds of the transfer of air masses in the atmosphere when ascending to a height of 15-20 kilometers, the probe may turn out to be tens or even hundreds of kilometers from the starting point, which makes it difficult to use such temperature profiles in weather forecasting tasks. At the same time, the probe rise time is 1.5–2 hours, which leads to a bias in the estimate of average temperature values due to violation of the stationarity condition.

Known lidar, in which temperature measurement is associated with remote determination of the molecular density of the atmosphere based on the Rayleigh scattering effect [Shibata T., Kobuchi M., Maeda M. Measurement of density and temperature profiles in the middle atmosphere with a XeF lidar // Applied Optics. 1986. V. 25. No. 5. PP 685-688] and the subsequent restoration of the temperature profile, assuming hydrostatic equilibrium of the atmosphere. The initial information for this type of lidar is the intensity of elastic scattering of the probe radiation, for which the contributions of molecular and aerosol scattering are fundamentally inseparable. The latter causes the main drawback of the method - it turns out to be workable only for the atmospheric region, where the effect of aerosol scattering can be neglected. Usually this is an interval of heights of 30-70 kilometers (stratosphere).

As a prototype, a lidar was chosen for measuring atmospheric temperature based on the effect of spontaneous Raman scattering (SCR) using an optical scrambler to equalize the hardware function (RU No. 160856 dated March 23, 2016). The known device includes a laser radiation source, at the output of which there is a transmitting optical system that sends laser radiation to the atmosphere. The radiation scattered backward enters the receiving telescope and then through the optical scrambler into a double polychromator, which selects the corresponding optical signals of the sections of purely rotational Raman spectra, which from the output of the polychromator through monofilament fibers arrive at the cathodes of photoelectronic multipliers (PMTs), which convert the optical signals into electrical . Further, the electrical signals are digitized and fed to the data processing unit, where the temperature calculation algorithm is performed, from the ratio of the signal intensities of the temperature-sensitive sections of the purely rotational Raman spectrum of nitrogen and oxygen molecules.

The disadvantage of this device is the long time to measure the temperature profiles of the atmosphere, due to the large amount of accumulation of signals necessary to obtain a given error of temperature measurement.

It is known that the signal accumulation time when measuring atmospheric temperature with respect to the intensities of sections of purely rotational Raman spectra of nitrogen and oxygen molecules is determined by both the scattering cross section and the temperature sensitivity slope of selected sections of the spectrum and is determined by the expression [Bobrovnikov S. M., Matvienko G. G. ., Romanovsky O.A., Serikov I.B., Sukhanov A.Ya. Lidar spectroscopic gas analysis of the atmosphere // Tomsk. Publishing House of IOA SB RAS. 2014.510 s. - ISBN 978-5-94458-148-8].

и

- средние частоты следования фотоотсчетов лидарных сигналов для участков спектра с отрицательной и положительной зависимостью от температуры соответственно;

- отношение интенсивностей термочувствительных участков спектра; ΔT - погрешность измерения температуры, К;

- крутизна температурной чувствительности отношения сигналов. Интенсивности сигналов

и

определяются энергетическими характеристиками лидара, в то время как крутизна температурной чувствительности отношения сигналов определяется положением выбранных участков в спектре СКР. При этом время накопления квадратично зависит от крутизны температурной чувствительности отношения.where -

and

- average repetition frequencies of photocounts of lidar signals for spectral regions with a negative and positive temperature dependence, respectively;

- the ratio of the intensities of heat-sensitive parts of the spectrum; ΔT is the error of temperature measurement, K;

- the steepness of the temperature sensitivity of the signal ratio. Signal intensities

and

are determined by the energy characteristics of the lidar, while the steepness of the temperature sensitivity of the signal ratio is determined by the position of the selected sections in the Raman spectrum. In this case, the accumulation time quadratically depends on the steepness of the temperature sensitivity of the ratio.

In the prototype under consideration, the selected sites are centered on the sixth and twelfth lines of the purely rotational spectrum of SCR on nitrogen molecules. The choice of sites was determined by the dispersion of the monochromator and the size of the applied fibers, providing reliable selection of sites and suppressing the background of the unbiased scattering line. Moreover, as the calculation shows, the steepness of the temperature sensitivity of the signal ratio is not optimal. This is due to the relatively large time of signal accumulation.

In this regard, in order to reduce the signal accumulation time, it is proposed to increase the steepness of the temperature sensitivity of the ratio by highlighting in the double polychromator not sixth and twelfth lines of the Stokes and anti-Stokes bands of the purely rotational Raman spectrum on nitrogen molecules, as in the prototype, and the fourth and twelfth lines, while maintaining this adequately suppresses the background of the line of unbiased scattering. As the calculation shows, the use of the fourth and twelfth lines instead of the sixth and twelfth ones makes it possible to increase the steepness of the temperature sensitivity of the ratio by 1.18 times and, accordingly, reduce the signal accumulation time by 1.4 times.

To solve this problem, it is necessary to use monofilament fibers with a smaller diameter, which will lead to the use of a narrow field of view of the lidar transceiver system. The use of a narrow lidar field of view requires the use of a laser with diffraction divergence of radiation and a laser expander to reduce the divergence of laser radiation to a value smaller than the field of view of the lidar receiving system. In addition, the narrow field of view of the lidar imposes certain restrictions on the mechanical stability and operational characteristics of the lidar system.

A smaller fiber diameter is one of the possible technical means, which makes it possible to distinguish the fourth and twelfth lines of the Stokes and anti-Stokes bands of the purely rotational Raman spectrum of nitrogen molecules. The novelty of the utility model is the use of the fourth and twelfth lines of the Stokes and anti-Stokes bands of the purely rotational Raman spectrum on nitrogen molecules, which will lead to an increase in the steepness of the temperature sensitivity of the ratio by 1.18 times and, accordingly, will reduce the signal accumulation time by 1.4 times Thus, using monofilament fibers with a smaller diameter, the fourth and twelfth lines of the Stokes and anti-Stokes bands of the purely rotational Raman spectrum on nitrogen molecules are distinguished in a double polychromator in with the adequate background suppression line unbiased scattering. The use of the fourth and twelfth lines will increase the steepness of the temperature sensitivity of the ratio by 1.18 times and, accordingly, reduce the signal accumulation time by 1.4 times.

A block diagram of the proposed lidar is shown in FIG. one.

The lidar for remote measurement of troposphere temperature consists of: 1 - a laser operating at a wavelength of 355 nm; 2 - transmitting optical system; 3 - receiving telescope; 4 - optical scrambler; 5 - double polychromator; 6, 7 - photomultiplier tubes (PMT 1, PMT 2,); 8 - data processing unit. All blocks and nodes of the lidar are located and fixed on one base and are in constructive unity.

The principle of operation of the proposed lidar system is as follows. The beam formed in the laser (1), through the transmitting optical system (2) is sent to the atmosphere. When propagating in the atmosphere, laser radiation undergoes scattering, including Raman scattering. The radiation scattered in the backward direction enters the receiving telescope (3) and then through the optical scrambler (4) into the double polychromator (5), which selects sections of the purely rotational Raman spectrum on nitrogen and oxygen molecules. The signals of the temperature-sensitive sections of the purely rotational spectrum of the SCR transmitted through the double polychromator are recorded using photoelectronic multipliers (6, 7), the electrical signals from which are fed to the data processing unit (8), where the electrical signals are converted digital, and then the temperature is calculated by the formula :

where I ₁₂ , I ₄ are the signal intensities of the fourth and twelfth lines of the Stokes and anti-Stokes bands of the purely rotational Raman spectrum on nitrogen molecules, respectively, α, β are the calibration constants of the hemochromators.

Claims (1)

Lidar for remote measurement of atmospheric temperature, including a laser source at the output of which there is a transmitting optical system that sends laser radiation to the atmosphere, a receiving telescope, the output of which is connected via an optical scrambler to the input of a double polychromator, which selects the corresponding optical signals of a purely rotational Raman spectrum, the output of a polychromator through monofilament fibers is optically coupled to the input of photomultiplier tubes (PMTs), the transform optical signals into electrical signals, the output of which is connected to a data processing unit for calculating the temperature, characterized in that the fourth and twelfth lines of the Stokes and anti-Stokes bands of the purely rotational Raman spectrum of nitrogen molecules are distinguished in the double polychromator, which will lead to an increase in the steepness of the temperature sensitivity of the ratio 1.18 times and accordingly will reduce the signal accumulation time by 1.4 times.

Images