CN116399764B - Inversion method, system and equipment for extinction cross section efficiency of pollution source particulate matters - Google Patents

Abstract

The invention discloses a pollution source particulate matter extinction cross section efficiency inversion method, system and equipment, and relates to the field of environment detection, wherein the method comprises the following steps: acquiring environmental parameters in the space range to be detected; the environmental parameters include optical parameters and concentrations of chemical species; determining uncertainty of each environmental parameter; inputting each of the environmental parameters and the uncertainty of each of the environmental parameters into a PMF source analytical model to obtain a source spectrogram, wherein the source spectrogram comprises a plurality of factors, each factor comprises a plurality of factors, and each factor comprises a chemical species and an optical parameter; determining pollution sources corresponding to the factors according to the concentration of each chemical species in the factors and the optical parameters; and inverting the extinction section efficiency of the particulate matters of each pollution source according to the concentration and the optical parameters of each chemical species corresponding to each pollution source. The difficulty in determining the extinction cross-section efficiency of each pollution source particulate matter is reduced.

Description

Inversion method, system and equipment for extinction cross section efficiency of pollution source particulate matters

Technical Field

The invention relates to the technical field of environmental monitoring, in particular to a method, a system and equipment for inverting extinction section efficiency of pollutant source particulate matters.

Background

Aerosols are an important component of the earth's atmosphere, and have profound effects on climate, air quality, ecosystem and human health, one of the important causes of air pollution. Where fine particulate matter (PM _2.5) can scatter and absorb solar short wave radiation, thereby severely affecting atmospheric visibility, past studies have only known the contribution of particulate matter chemistry to extinction, and it is difficult to convert it into an effective environmental remediation means, and it is therefore necessary to directly relate it to the extinction contribution of the pollution source in order to better support improved visibility.

The current calculation method of extinction section efficiency (Mass extinction efficiency, MEE) mainly carries out sampling monitoring at each specific pollution source, observes the concentration and optical parameters of PM _2.5 of each pollution source, and further calculates the extinction section efficiency of each pollution source. The disadvantage of this method is that the source sampling work needs to be performed for each pollution source, and the process is cumbersome.

Disclosure of Invention

The invention aims to provide a method, a system and equipment for inverting extinction section efficiency of pollutant source particles, which reduce difficulty in determining extinction section efficiency of each pollutant source particle.

In order to achieve the above object, the present invention provides the following solutions:

an inversion method of extinction cross-section efficiency of pollution source particulate matter, comprising the following steps:

acquiring environmental parameters in the space range to be detected; the environmental parameters include optical parameters and concentrations of chemical species;

determining uncertainty of each environmental parameter;

Inputting the environmental parameters and the uncertainty of the environmental parameters into a PMF source analysis model to obtain a source spectrogram, wherein the source spectrogram comprises a plurality of factors, each factor comprises a plurality of factors, and each factor is a chemical species or an optical parameter;

determining pollution sources corresponding to the factors according to the concentration of each chemical species in the factors and the optical parameters;

And inverting the extinction section efficiency of the particulate matters of each pollution source according to the concentration and the optical parameters of each chemical species corresponding to each pollution source.

The optical parameters include a light scattering coefficient and a light absorption coefficient.

Optionally, the chemical species includes a carbonaceous component and an inorganic element.

Optionally, the determining the uncertainty of each environmental parameter specifically includes:

when the concentration of the environmental parameter is greater than or equal to the preset minimum detection limit, according to the formula Calculating uncertainty of the environmental parameter;

when the concentration of the environmental parameter is less than the preset minimum detection limit, according to the formula Calculating uncertainty of the environmental parameter;

Wherein Unc represents uncertainty, errorFraction is error rate, concentration is concentration of the environmental parameter, and MDL is preset minimum detection limit.

Optionally, inverting the extinction section efficiency of the particulate matters of each pollution source according to the concentration and the optical parameters of each chemical species corresponding to each pollution source specifically comprises the following steps:

Calculating the extinction cross-sectional efficiency of one of the pollution sources according to the formula mee=b _ext/[PM_2.5 ];

Wherein MEE represents an extinction cross-sectional efficiency of the pollution source, b _ext represents an extinction coefficient corresponding to the pollution source, the extinction coefficient is a sum of the light scattering coefficient and the light absorption coefficient, and [ PM _2.5 ] represents a sum of concentrations of chemical species corresponding to the pollution source.

The invention also discloses an inversion system of extinction section efficiency of pollution source particulate matters, which comprises the following steps:

the environment parameter acquisition module is used for acquiring environment parameters in the space range to be detected; the environmental parameters include optical parameters and concentrations of chemical species;

An uncertainty determination module of the environmental parameters, which is used for determining the uncertainty of each environmental parameter;

The source spectrogram obtaining module is used for inputting the environmental parameters and the uncertainty of the environmental parameters into the PMF source analysis model to obtain a source spectrogram, wherein the source spectrogram comprises a plurality of factors, each factor comprises a plurality of factors, and each factor is a chemical species or an optical parameter;

the pollution source determining module is used for determining pollution sources corresponding to the factors according to the concentration and the optical parameters of the chemical species in the factors;

and the extinction section efficiency determining module is used for inverting the extinction section efficiency of each pollution source particle according to the concentration and the optical parameters of each chemical species corresponding to each pollution source.

The invention also discloses an electronic device, which comprises a memory and a processor, wherein the memory is used for storing a computer program, and the processor runs the computer program to enable the electronic device to execute the inversion method of the extinction cross section efficiency of the pollution source particulate matters.

According to the specific embodiment provided by the invention, the invention discloses the following technical effects:

According to the invention, the source spectrogram is obtained through the PMF source analysis model, each pollution source is determined according to the source spectrogram, so that the extinction cross section efficiency of each pollution source is determined, each pollution source is prevented from being subjected to source sampling, and the difficulty in determining the extinction cross section efficiency of each pollution source particulate matter is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions of the prior art, the drawings that are needed in the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic flow chart of an inversion method of extinction cross-section efficiency of pollutant source particulate matter;

FIG. 2 is a schematic diagram of an inversion method of extinction cross-section efficiency of contaminant source particulate matter according to the present invention;

FIG. 3 is a schematic diagram of an inversion system for extinction cross-section efficiency of contaminant source particulate matter according to the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The invention aims to provide a method, a system and equipment for inverting extinction section efficiency of pollutant source particles, which reduce difficulty in determining extinction section efficiency of each pollutant source particle.

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to the appended drawings and appended detailed description.

Example 1

As shown in FIG. 1, the inversion method of the extinction section efficiency of the pollution source particulate matter comprises the following steps:

Step 101: acquiring environmental parameters in the space range to be detected; the environmental parameters include optical parameters and concentrations of chemical species.

The optical parameters include a light scattering coefficient b _scat and a light absorption coefficient b _abs.

The chemical species include carbonaceous components and inorganic elements.

Step 102: and determining uncertainty of each environmental parameter.

The determining the uncertainty of each environmental parameter specifically comprises the following steps:

when the concentration of the environmental parameter is greater than or equal to the preset minimum detection limit, according to the formula And calculating uncertainty of the environmental parameter.

When the concentration of the environmental parameter is less than the preset minimum detection limit, according to the formula And calculating uncertainty of the environmental parameter.

Wherein Unc represents uncertainty, error Fraction is Error rate, concentration is concentration of the environmental parameter, and MDL is preset minimum detection limit. The setting range of the Error Fraction is 5% -20%.

The principle of the inversion method of the extinction cross-section efficiency of the pollution source particulate matters is shown in figure 2. The chemical components in fig. 2 are chemical species, and the optical parameters include a light scattering coefficient b _scat, a light absorption coefficient b _abs, and a sum extinction coefficient b _ext, and PMF represents a PMF source analytical model.

Step 103: inputting each environmental parameter and uncertainty of each environmental parameter into a PMF source analysis model to obtain a source spectrogram, wherein the source spectrogram comprises a plurality of factors, each factor comprises a plurality of factors, and each factor is a chemical species or an optical parameter.

The contribution rate of each factor to the concentration of PM _2.5 can be derived in the source spectrum.

The PMF source analysis model principle is to decompose a sample data matrix X into a factor component spectrum matrix F and a factor contribution matrix G, and the formula is as follows:

Where X _ij is the element in the sample data matrix X, F _ki is the element in the factor component spectrum matrix F, G _ik is the element in the factor contribution matrix G, X _ij represents the concentration of the jth species in the ith sample, P is the number of factors, G _ik represents the factor contribution of the kth factor to the ith sample, F _kj is the factor distribution of the jth species on the kth factor, e _ij is the residual of the jth species measured on the ith sample.

The PMF source analysis model seeks the minimum solution of the objective function Q according to the input concentration and uncertainty (u _ij) to obtain the factor spectrum and factor contribution information, and the formula is as follows:

Wherein n represents the number of samples and m represents the number of species

Step 104: and determining a pollution source corresponding to each factor according to the concentration of each chemical species in each factor and the optical parameter.

The content of each pollution source tracer is used to determine which pollution source the factor represents.

The concentration ranges of the elements corresponding to the pollution sources are stored in advance, and the pollution sources corresponding to the factors are determined according to the relation among the concentration ranges of the elements corresponding to the pollution sources stored in advance.

For example, when the K ⁺ and Cl ^- levels are above the corresponding set points, the factor is considered to be the result of biomass combustion, i.e., the pollution source to which the factor corresponds is biomass combustion.

Step 105: and inverting the extinction section efficiency of the particulate matters of each pollution source according to the concentration of each chemical species and optical parameters corresponding to each pollution source.

Step 105 specifically includes:

The extinction cross-sectional efficiency of one of the sources is calculated according to the formula mee=b _ext/[PM_2.5.

Wherein MEE represents the extinction cross-sectional efficiency of the pollution source, b _ext represents the extinction coefficient corresponding to the pollution source, namely the sum of the light scattering coefficient b _scat and the light absorption coefficient b _abs, and [ PM _2.5 ] represents the sum of the concentrations of the chemical species corresponding to the pollution source.

Example 2

FIG. 3 is a schematic structural diagram of an inversion system for extinction cross-section efficiency of particulate matter of a pollution source according to the present invention, as shown in FIG. 3, the inversion system for extinction cross-section efficiency of particulate matter of a pollution source includes:

An environmental parameter obtaining module 201, configured to obtain environmental parameters within a space range to be detected; the environmental parameters include optical parameters and concentrations of chemical species.

An uncertainty determination module 202 for determining uncertainty of each of the environmental parameters.

The source spectrogram obtaining module 203 is configured to input each of the environmental parameters and uncertainty of each of the environmental parameters into a PMF source analytical model to obtain a source spectrogram, where the source spectrogram includes a plurality of factors, each factor includes a plurality of elements, and each element is a chemical species or an optical parameter.

The pollution source determining module 204 is configured to determine a pollution source corresponding to each factor according to the concentration of each chemical species in each factor and the optical parameter.

And the extinction section efficiency determining module 205 is configured to invert the extinction section efficiency of each pollution source particulate matter according to the concentration and the optical parameters of each chemical species corresponding to each pollution source.

Example 3

The embodiment discloses an electronic device, which comprises a memory and a processor, wherein the memory is used for storing a computer program, and the processor runs the computer program to enable the electronic device to execute the inversion method of the extinction cross-section efficiency of pollution source particles in embodiment 1.

In the present specification, each embodiment is described in a progressive manner, and each embodiment is mainly described in a different point from other embodiments, and identical and similar parts between the embodiments are all enough to refer to each other. For the system disclosed in the embodiment, since it corresponds to the method disclosed in the embodiment, the description is relatively simple, and the relevant points refer to the description of the method section.

The principles and embodiments of the present invention have been described herein with reference to specific examples, the description of which is intended only to assist in understanding the methods of the present invention and the core ideas thereof; also, it is within the scope of the present invention to be modified by those of ordinary skill in the art in light of the present teachings. In view of the foregoing, this description should not be construed as limiting the invention.

Claims (5)

1. An inversion method of extinction cross-section efficiency of pollutant source particulate matter is characterized by comprising the following steps:

Acquiring environmental parameters in the space range to be detected; the environmental parameters include optical parameters and concentrations of chemical species; the optical parameters include a light scattering coefficient and a light absorption coefficient;

determining uncertainty of each environmental parameter;

Inputting the environmental parameters and the uncertainty of the environmental parameters into a PMF source analysis model to obtain a source spectrogram, wherein the source spectrogram comprises a plurality of factors, each factor comprises a plurality of factors, and each factor is a chemical species or an optical parameter;

determining pollution sources corresponding to the factors according to the concentration of each chemical species in the factors and the optical parameters; the concentration ranges of the elements corresponding to the pollution sources are stored in advance, and the pollution sources corresponding to the factors are determined according to the relation among the concentration ranges of the elements corresponding to the pollution sources stored in advance;

Inverting the extinction section efficiency of each pollution source particle according to the concentration and optical parameters of each chemical species corresponding to each pollution source;

Inverting the extinction section efficiency of each pollution source particulate matter according to the concentration and optical parameters of each chemical species corresponding to each pollution source, wherein the extinction section efficiency comprises the following specific steps:

Calculating the extinction cross-sectional efficiency of one of the pollution sources according to the formula mee=b _ext/[PM_2.5 ];

Wherein MEE represents an extinction cross-sectional efficiency of the pollution source, b _ext represents an extinction coefficient corresponding to the pollution source, the extinction coefficient is a sum of the light scattering coefficient and the light absorption coefficient, and [ PM _2.5 ] represents a sum of concentrations of chemical species corresponding to the pollution source.

2. A method of inverting the extinction cross-sectional efficiency of a contaminant source particulate matter according to claim 1, wherein said chemical species comprises a carbonaceous component and an inorganic element.

3. The method for inverting the extinction cross-section efficiency of particulate matter of a pollution source according to claim 1, wherein said determining uncertainty of each of said environmental parameters comprises:

when the concentration of the environmental parameter is greater than or equal to the preset minimum detection limit, according to the formula Calculating uncertainty of the environmental parameter;

when the concentration of the environmental parameter is less than the preset minimum detection limit, according to the formula Calculating uncertainty of the environmental parameter;

Wherein Unc represents uncertainty, errorFraction is error rate, concentration is concentration of the environmental parameter, and MDL is preset minimum detection limit.

4. An inversion system for extinction cross-section efficiency of a contaminant source particulate, comprising:

the environment parameter acquisition module is used for acquiring environment parameters in the space range to be detected; the environmental parameters include optical parameters and concentrations of chemical species; the optical parameters include a light scattering coefficient and a light absorption coefficient;

An uncertainty determination module of the environmental parameters, which is used for determining the uncertainty of each environmental parameter;

The source spectrogram obtaining module is used for inputting the environmental parameters and the uncertainty of the environmental parameters into the PMF source analysis model to obtain a source spectrogram, wherein the source spectrogram comprises a plurality of factors, each factor comprises a plurality of factors, and each factor is a chemical species or an optical parameter;

The pollution source determining module is used for determining pollution sources corresponding to the factors according to the concentration and the optical parameters of the chemical species in the factors; the concentration ranges of the elements corresponding to the pollution sources are stored in advance, and the pollution sources corresponding to the factors are determined according to the relation among the concentration ranges of the elements corresponding to the pollution sources stored in advance;

The extinction section efficiency determining module is used for inverting the extinction section efficiency of each pollution source particle according to the concentration and the optical parameters of each chemical species corresponding to each pollution source;

Inverting the extinction section efficiency of each pollution source particulate matter according to the concentration and optical parameters of each chemical species corresponding to each pollution source, wherein the extinction section efficiency comprises the following specific steps:

Calculating the extinction cross-sectional efficiency of one of the pollution sources according to the formula mee=b _ext/[PM_2.5 ];

Wherein MEE represents an extinction cross-sectional efficiency of the pollution source, b _ext represents an extinction coefficient corresponding to the pollution source, the extinction coefficient is a sum of the light scattering coefficient and the light absorption coefficient, and [ PM _2.5 ] represents a sum of concentrations of chemical species corresponding to the pollution source.

5. An electronic device comprising a memory for storing a computer program and a processor that runs the computer program to cause the electronic device to perform the method according to any one of claims 1 to 3.