RU2331867C1 - Interference-proof resonance spectral gas analyser - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention concerns analytical instrument engineering and can be applied in precision measurement of gas concentrations, high-precision odour identification, and in crime detection. Gas analyser includes power unit, lighting element, optical cell, radiation receiver, optical system, light detector, amplifier, analog-to-digital converter, control unit, digital-to-analog converter. Lighting element is a laser, and between it and the optical cell a decoherentor is placed. Gas analyser is additionally equipped with odour image forming, storage and identification units connected to the control unit.

EFFECT: improved sensitivity and interference protection of gas concentration gauge.

1 dwg

Description

The invention relates to analytical instrumentation and can be used for precision measurement of concentrations of gaseous substances and high-precision identification of odors. The device is most in demand in forensics.

Known technical solution according to the patent RU 2083959, IPC 6 G01J 3/42, from 21.03.95, publ. 07/10/97, Bulletin No. 19, “METHOD FOR MEASURING GAS CONCENTRATION BY THE CORRELATION FOURIER SPECTROSCOPY METHOD” [2].

The invention relates to methods for measuring gas concentrations in gaseous media by absorption spectroscopy, in particular to methods for measuring gaseous impurities in the atmosphere and controlling environmental pollution. The method of correlation Fourier spectroscopy involves measuring the intensities of a specific set of components of the Fourier spectrum of the received radiation, and the values of the Fourier variables of the measured Fourier components correlate with the positions of the maxima and minima in the Fourier spectrum of the absorption spectrum of the measured gas, and the received radiation is analyzed only in the wave number range where the measured gas has absorption lines.

The disadvantage of this method is the relatively low sensitivity, since for noticeable absorption of radiation it is necessary that the concentration of the desired substance be sufficiently large (at least 0.001%).

The technical solution according to patent No. 2035717 of 06/01/92, publ. 05.20.95, bulletin No. 14, IPC 6 G01N 21/61 “Correlation gas analyzer”, which is equipped with a separation unit, a sampling-comparison unit and a control unit, while the output of the radiation receiver unit is connected to the input of the separation unit, the first and second outputs of which connected respectively to the first and second inputs of the sampling-comparison and signal processing units, the output of the sampling-comparison unit through the control unit is connected to the control input of the separation unit, and its control input is connected to the synchronization unit [3].

Such an analyzer has low measurement accuracy due to the mutual instability of the intensity of the radiation incident on the medium being analyzed and the radiation intensity of the reference emitter.

In addition, this device does not allow real-time determination of the presence of the desired substance if it is present in the gas, but its concentration is so small that it does not cause noticeable absorption of electromagnetic radiation at a given wavelength, i.e. lies below the sensitivity threshold of the device [1].

The closest in technical essence is the technical solution for the patent for a spectral gas analyzer (PM 51744, application 2005131258 from 02.27.06, bulletin No. 6), containing a power supply unit, a lighting element, an input photocell, an optical cuvette, a radiation receiver, an output photocell, an optical system , photodetector, amplifier, analog-to-digital converter, control unit, digital-to-analog converter [7].

The main disadvantage of such a scheme is its complexity and insecurity from external influences. In particular, even a slight desynchronization of the shutter operation completely destroys the device. The reason for this is that the mechanical shutter system introduces errors in the operation of the device due to vibrations, and the electron-optical system needs an expensive and complex electronic synchronization system that is sensitive to any external electromagnetic interference. In addition, this system is not designed to work in cumulative mode. In addition to this, a fundamental drawback of this method is the impossibility of identifying a substance contained in air or gas that is not in the instrument database. This drawback makes it completely unsuitable for identifying individual odors of individual technical and biological objects.

The objective of the proposed technical solution is to significantly increase the sensitivity and noise immunity of a device for measuring gas concentration by the method of correlation Fourier spectroscopy (RU 2083959, IPC 6 G01J 3/42) [2], as well as expanding the functionality of a spectral gas analyzer for identifying odors of technical and biological objects.

The problem is solved due to the fact that the noise-protected resonant spectral gas analyzer containing a power supply, to the output of which a lighting element, a photodetector and amplifier are connected, and a control unit is connected to the input via a digital-to-analog converter, as well as a cuvette to which a spectral element is connected, an optical system, photodetector, amplifier, analog-to-digital converter and control unit, while a laser operating in a pulsed or pulsed-periodic mode, a decoder is located between the laser and the cuvette, and the gas analyzer is additionally equipped with units for generating odor images, storing odor images and recognizing odor images attached to the control unit.

Using a laser as a lighting element allows, due to the operation in a pulsed or pulsed-periodic mode, to abandon a complex and not sufficiently noise-protected photo shutter system, to carry out selective resonant excitation of molecular levels of the analyzed substances, and to significantly increase the sensitivity of devices compared to the prototype.

The use of a decoherer (a stochastically uneven transparent plate having characteristic microrelief unevenness sizes comparable with the wavelength of laser radiation) located between the laser and the cell allows optimizing the radiation pattern of the resonance fluorescence of the desired substances or their combinations (smells).

The inclusion in addition to the scheme of blocks for generating odor images, storing an odor image and recognizing an odor image allows you to use the device not only to search for a fixed set of substances, information about which is contained in the control unit of the device, but also to create an information database of electronic images of individual odors created by technical and biological objects, that is, to produce self-learning device.

The proposed scheme of an interference-protected resonant spectral gas analyzer, which uses an optical cuvette and a control unit, the software of which includes data on the spectral characteristics of the analyte and a signal processing program, as well as a gas analyzer control program, allows you to create and analyze the emission spectrum of a certain substance, as in existing prototype. However, it is more reliable in operation, since it does not contain a complex and insufficiently stable system of synchronized photo shutters. Using a laser as a lighting element in the prototype allows you to emulate the operation of photo shutters by choosing the shape and duration of the pulse. The pulsed-periodic laser operation mode ensures the operation of the photodetector in the storage mode. Such a device has all the advantages of a prototype, but is more reliable and sensitive compared to it. However, the use of a laser as a lighting element has not only undeniable advantages, but also obvious disadvantages. In particular, to achieve maximum sensitivity of the device, it must be tuned to the resonant fluorescence mode of the substance being sought. Tunable wavelength lasers allow you to fine-tune the device to search for the desired substance. However, this raises another problem. The molecules of the desired substance are really most likely excited when the resonance condition is fulfilled (the frequency of the stimulating radiation coincides with the frequency of the corresponding transition in the excited molecule). However, in this case, the use of coherent radiation to excite molecules leads to the fact that during the deexcitation of molecules, the majority of transitions are forced transitions, and spontaneous transitions make only an insignificant contribution to the total number of transitions. This leads to the fact that the stimulated emission is directed in the same direction as the stimulating one. Such a directivity pattern of stimulated electromagnetic radiation arising from the deexcitation of molecules of the desired substance is not optimal from the point of view of the possibility of its separation from the stimulating radiation during registration of the output signal. To eliminate this drawback, it is necessary to use a decoder - a thin transparent plate having a statistically uneven surface, the scale of randomly distributed inhomogeneities of which is comparable with the wavelength of the laser illuminator. In this case, it is possible to preserve all the advantages of using a laser as a lighting element and at the same time eliminate the problem of the contribution of forced transitions.

The action of the device, as in the prototype, is based on the fact that the spectral lines of each substance have a certain width, and at the same time it is impossible to simulate the wavelength and line width. Therefore, the identification of odors is made with a very high degree of probability.

The ability to analyze the emission spectra of the proposed device makes it possible to detect the desired substances even in the case of negligible concentrations, since modern photodetectors are capable of detecting literally individual photons.

Using special software in the control unit allows you to analyze the composition of the gas mixture in a few seconds. Therefore, the analysis of the composition of the gas mixture can be carried out in real time.

The gas analyzer of the described type has not too large dimensions and weight and can be performed both in a stationary and a portable version.

The technical result of the proposed technical solution is the creation of an interference-protected resonant spectral gas analyzer by introducing a laser with a decoder and using additional units for the formation, storage and recognition of odor patterns attached to the control unit, making this device suitable not only for determining the concentration of substances, but also for identifying odors technical and biological objects, the possibility of its work in recognition mode and in self-learning mode, which rivodit to expand the functionality of the proposed device.

The drawing shows a block diagram of a spectral gas analyzer containing a power supply 1, a laser 2 decoder 3, an optical cuvette 4, a spectral element 5, an optical system 6, a photodetector 7, an amplifier 8, an analog-to-digital converter (ADC) 9, a control unit 10, a digital-to-analog converter (DAC) 11, an odor imaging unit 12, an odor image storage unit 13, and an odor image recognition unit 14.

The spectral gas analyzer is made as follows.

A laser 2, a photodetector 7, an amplifier 8 are connected to the output of the power supply unit 1, and a control unit 10 is connected to the input through a digital-to-analog converter (DAC) 11. Laser 2, decoder 3, and cuvette 4 are connected by a beam of light passing through them.

A spectral element 5, an optical system 6 for transmitting the analyzed signal to a photodetector 7, which makes it possible to register the emitted optical signal in a predetermined spectral range, an amplifier 8 of an electric signal coming from a photodetector 7, an analog-to-digital converter (ADC) 9, are connected sequentially to the cell 4; control unit 10, which includes a database of spectral characteristics of the analyzed substances, as well as a gas analyzer control program, to the control unit Control units are attached to the formation of odor images, storage of the image of smells and recognition of the image of smells.

Noise-protected resonant spectral gas analyzer can operate in self-learning mode and in recognition mode as follows.

The operation of this device is based on the use of the duality principle in the control unit (Yu.L. Ratis, 1984) for the numerical Fourier transform (see [4] - [6]). According to the duality principle, in the numerical or hardware integration of functions having sharp peaks (for example, spectral lines or bands in the radiation or absorption spectrum), it is necessary to consider the problem of recognizing an image (signal) both for the function itself and for its Fourier image. Since the delta peak in the coordinate space turns into a substrate function in the Fourier conjugate space and, conversely, the simultaneous numerical or hardware analysis of both the function itself and its Fourier transform allows minimizing the probability of a substance identification error by determining the qualitative composition of the gas mixture radiation spectra, as well as increase the accuracy and sensitivity of the device.

Initially, the control unit 10 through the DAC 11 and the power supply 1, turns on the laser 2, operating in a pulsed or pulse-periodic mode. As a result of pulsed illumination of the optical cuvette 4 through decoherer 3, a stochastically uneven transparent plate having characteristic microrelief irregularities commensurate with the wavelength of the laser radiation, some of the atoms and molecules that make up the analyzed gas mixture go into an excited state, but because the laser radiation after passing through the decoherer, it loses the coherence property, so that the stimulated emission of the excited molecules is suppressed, which allows optimizing l radiation pattern of the resonance fluorescence of the desired substances or their combinations (odors).

Under deexcitation, these atoms and molecules emit electromagnetic radiation in the infrared, visible and, in some cases, in the ultraviolet range, which enters the spectral element 5, where the light pulse formed in the optical cell 4 is decomposed into a spectrum.

After that, through the optical system 6, the light pulse enters the photodetector 7.

After the optoelectric conversion, the electric signal enters the amplifier 8, from which the signal through the ADC 9 enters the control unit 10 for digital information processing.

From the control unit 10, depending on whether the device is in training or search mode, the signal passes through blocks 12 and 13 or through blocks 14 and 13, after which the signal is fed back to the control unit 10.

The control unit 10 processes the input signal using an algorithm that uses the principle of duality, and provides information about the chemical composition of the test gas mixture and the source of the detected odor.

The system of spectral windows is built taking into account the fact that many molecular compounds have fairly long-lived levels in the infrared, optical, and even in the ultraviolet wavelength range. For the spectral range ω _i ≤ω≤ω _i + Δω _i . the output signal is recorded by the detector, where ω is the cyclic frequency of electromagnetic radiation emitted by atoms and molecules of the substance located in the optical cuvette 4, ω _i is the lowest cyclic frequency for the ith channel (spectral range), Δω _i is the width of the spectral window.

BIBLIOGRAPHY

1. D.V. Sivukhin. General physics course, v.4. Optics. M .: Nauka, Main Edition of Physics and Mathematics, 1980, 752 p.

2. RU 2083959, IPC 6 G01J 3/42, dated 21.03.95, publ. 07/10/97, bull. No. 19, "A method of measuring gas concentrations by the method of correlation Fourier spectroscopy."

3. RU No. 2035717 of 06/01/92, publ. 05/20/95, bull. No. 14, IPC 6 G01N 21/61, “Correlation gas analyzer”.

4. Yu.L. Ratis, M.L. Kalyaev. Collective phenomena in heat-resistant coatings during thermal shock, Dep. VINITI, No. 6594-84 of 08/10/1984

5. Yu.L. Ratis, V.V. Stolyar. A generalized Kalecki model for describing the economy of large cities. Market economy. Status, problems, prospects. Department of Economics, Russian Academy of Sciences, MIR, Samara, 1998, 6 pp.

6. Yu.L. Ratis, G.I. Leonidovich, A. Yu. Melnikov, Light flux diffraction of fiber - optical and optical electronic transducers of mechanical displacement. Proceedings of SPIE, volume 3348, Computer and Holographic Optics and Image Processing, 1997, p.336.

7. G.Yu. Ratis, N.N. Konkov. RF patent PM 51744, application 2005131258 dated 02.27.06, bulletin No. 6.

Claims (1)

An interference-protected resonant spectral gas analyzer containing a power supply, to the output of which a lighting element, a photodetector and an amplifier are connected, and a control unit is connected to the input through a digital-to-analog converter, as well as a cuvette to which a spectral element, an optical system, a photodetector, an amplifier, and an analog- a digital converter and a control unit, characterized in that a laser operating in a pulse or pulse-period is used as a lighting element eskom mode between the laser and the cuvette is dekogerentor analyzer and is further provided with image forming units odors, odors storing images and image recognition of odors attached to the control unit.