CN101144736A - Comparison method of different types of spectrometers - Google Patents
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- CN101144736A CN101144736A CNA2007100189742A CN200710018974A CN101144736A CN 101144736 A CN101144736 A CN 101144736A CN A2007100189742 A CNA2007100189742 A CN A2007100189742A CN 200710018974 A CN200710018974 A CN 200710018974A CN 101144736 A CN101144736 A CN 101144736A
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Abstract
A method for comparing different types of spectrometers includes obtaining spectrum resolution at the shortest wavelength from data of an equal wavelength spectrum resolution spectrometer, obtaining the maximum optical path difference of interference data from data of the equal wave number resolution spectrometer, carrying out Fourier transform, using the maximum optical path difference as apodization function parameter of interference pattern after Fourier transform of data of the equal wavelength spectrum resolution spectrometer, carrying out rectangular apodization and inverse Fourier transform, and comparing parameters of spectrum intensity, spectrum line position or spectrum resolution between corrected spectrum pattern of the equal wavelength spectrum resolution spectrometer and spectrum pattern of the equal wave number spectrum resolution spectrometer to be compared in overlapped spectrum range. The invention solves the technical problems of difficult checking and calibration and high cost by using different types of spectrometers in the technical background. The invention can quantitatively check and calibrate the radiance of various interference spectrometers or interference imaging spectrometers by using a prism or grating spectrometer with higher radiation accuracy.
Description
Technical field
The present invention relates to a kind of result and unite, make it the method that can contrast mutually, relate in particular to the control methods of a kind of color dispersion-type spectrometer and interference type spectral instrument measure spectrum between the dissimilar spectrometers.
Technical background
The spectrometer principle mainly is divided into two kinds: a kind of is to be the color dispersion-type spectrometer of dispersion element with prism and grating, can directly obtain the spectrum of target.Another kind is to be the interference type spectral instrument of core with Mai Shi or Sagnac interferometer, and the interference strength that can directly obtain target distributes, and needs just can obtain target optical spectrum through Fourier transform.
The spectral resolution of color dispersion-type spectrometer is represented with wavelength X, basically be with wavelength uniformly-spaced, this feature is called " equiwavelength's resolution ", and the spectral resolution of interference type spectral instrument is then represented with wave number σ, be uniformly-spaced, be referred to as " etc. wavenumber resolution " with wave number.When wave number was converted into wavelength, its resolution is the shortwave height always, and long wave is low, becomes unequal interval.So the spectrum that color dispersion-type spectrometer, the instrument of this two classes different principle of interference type spectral instrument obtain can't directly be checked comparison.
The spectrometer of specific use and imaging spectrometer especially for the interference type imaging spectrometer of spacer remote sensing, are produced the later stage and all will be checked and demarcate.Portable have the high light spectral resolution (~2nm) wide spectrum mainly be a grating dispersion type spectrometer, as the portable spectrum radiancy meter (FieldSpec@pro) of ASD company.Adopt dissimilar spectrometers to check and demarcate, promptly directly the spectrum of color dispersion-type spectrometer and the acquisition of interference type spectral instrument is compared, owing to differ greatly, not only can't carry out quantitative checking, even comparison is all very difficult qualitatively.If adopt spectrometer of the same type to check and demarcate, then need special-purpose higher check of the same type and the calibration facility of precision of a cover, the cost height, and design, manufacture difficulty are big.
Summary of the invention
The object of the present invention is to provide a kind of control methods of dissimilar spectrometers, it has solved and has checked and demarcate with dissimilar spectrometers in the technical background, and qualitative comparison difficulty can't be carried out quantitative checking; Check and demarcate with spectrometer of the same type, cost height, and design, technical matters that manufacture difficulty is big.
Technical solution of the present invention is as follows:
A kind of control methods of dissimilar spectrometers, this method comprises following performing step:
(1.1) obtain the spectral resolution δ σ of minimal wave length from equiwavelength's spectral resolution spectrometer data
0, from etc. wavenumber resolution spectrometer data obtain the maximum optical path difference Δ of interference data
Max
(1.2) carry out Fourier transform: reciprocity wave spectrum resolution spectrometer data are carried out Fourier transform successively, and the intermediate result that obtains the data processing of equiwavelength's spectral resolution spectrometer is interferogram;
(1.3) choose and cut the toe parameter: the maximum optical path difference Δ
MaxApodizing function parameter as interferogram behind equiwavelength's spectral resolution spectrometer data Fourier transform;
(1.4) carry out rectangle and cut toe: the dot product width is a Δ on the interferogram that equiwavelength's spectral resolution spectrometer data Fourier transform obtains
MaxThe rectangle apodizing function;
(1.5) carry out inverse fourier transform: the interferogram of cutting toe through rectangle is carried out inverse fourier transform, obtain the correction spectrogram of equiwavelength's spectral resolution spectrometer spectroscopic data;
(1.6) compare: in the overlapping spectra segment limit, the spectrogram of the correction spectrogram of reciprocity wave spectrum resolution spectrometer and wave number spectral resolution spectrometer such as to be compared carries out the contrast of major parameters such as spectral intensity, position of spectral line, spectral resolution.
The above equiwavelength's spectral resolution spectrometer to be compared is at the spectral resolution δ of short-wave band σ
0To satisfy
Be advisable.
The function of cutting toe behind the above equiwavelength's spectral resolution spectrometer Fourier transform to be compared is a rectangular function, and the parameter of this rectangular function is good with the maximum optical path difference that adopts wave number spectral resolution spectrometer such as to be compared.
The above equiwavelength's spectral resolution spectrometer to be compared can be color dispersion-type spectrometer, wedge optical filter type spectrometer or acoustooptic modulation type spectrometer, also can be color dispersion-type imaging spectrometer, wedge optical filter type imaging spectrometer or acoustooptic modulation type imaging spectrometer; Described wave number spectral resolution spectrometer such as to be compared can be interference type spectral instrument or interference type imaging spectrometer.
Above-described color dispersion-type spectrometer can be the color dispersion-type spectrometer of prismatic decomposition mode or grating beam splitting mode, and described color dispersion-type imaging spectrometer can be the color dispersion-type imaging spectrometer of prismatic decomposition mode or grating beam splitting mode.
The present invention has following advantage:
1. after adopting the inventive method to handle, two spectrograms that dissimilar spectrometers obtain have identical spectra resolution, can make the quantification comparison result to features such as spectral intensity, position of spectral line.
The present invention be applicable to equiwavelength's spectral resolution spectrometer and etc. the comparison between the wave number spectral resolution spectrometer.Obtain the imaging spectrometer that equiwavelength's spectral resolution spectrometer comprises color dispersion-type spectrometer, wedge optical filter type spectrometer, acoustooptic modulation type spectrometer and above several forms; Wave number spectral resolution spectrometer such as obtain and refer to various forms of interference type spectral instrument, interference type imaging spectrometer.
3. the radiancy that can quantitatively check and demarcate various types of interference type spectral instrument or interference type imaging spectrometer with higher prism of radiation accuracy or grating spectrograph.
4. the interference type spectral instrument is compared with the spectrometer of other types and is had higher position of spectral line accuracy, can be used for checking and demarcating the position of spectral line of various forms of equiwavelength's spectral resolution spectrometers such as color dispersion-type, wedge optical filter type and acoustooptic modulation type.
5. the present invention need not to increase the hardware input, and cost is low.
6. comparison realizes simple, convenient, time saving and energy saving.
Description of drawings
Fig. 1 is a treatment scheme synoptic diagram of the present invention.
Embodiment
The principle of the invention is analyzed:
1. be example with the quasi-monochromatic light, wavelength is λ, and wave number is σ.If the wavelength resolution of spectrometer is δ λ, be δ σ to this quasi-monochromatic light wavenumber resolution
0
(1.1) adopt the color dispersion-type spectrometer, then at wavenumber domain, the test spectral B that the color dispersion-type spectrometer obtains
s(σ) relation with original spectrum B (σ) is as follows:
Wherein, " * " is the convolution algorithm symbol, and " " is the point multiplication operation symbol.
(1.2) for same spectrum, because there is a maximum optical path difference Δ in the limitation of interference type spectral instrument interferogram sampling
Max, the test spectral B that causes the interference type spectral instrument to obtain
g(σ) relation with original spectrum B (σ) is as follows:
(1.3) the two is relatively the time, and the spectrum that the color dispersion-type spectrometer is obtained carries out conversion with the interfere type principle, and with the maximum optical path difference Δ of interference spectroscope
MaxFor the rectangular function of parameter cuts toe, i.e. rectangular function of dot product on the interference spectrum behind the Fourier transform
Then test conversion spectrum B
S-g(σ) relation with original spectrum B (σ) is as follows:
Test spectral B with the acquisition of interference type spectral instrument
g(σ) compare, because the restriction of the resolution of color dispersion-type spectrometer own, at test conversion spectrum B
S-gIntroduce the Sinc apodizing function (σ), will be to test conversion spectrum B
S-gSpectral resolution (σ) exerts an influence.
According to by Sinc apodizing function and rectangular function the character of the common apodizing function of determining, can obtain:
When
The time, to test conversion spectrum B
S-gSpectral resolution (σ) does not exert an influence.
When
The time, to test conversion spectrum B
S-gSpectral resolution (σ) can exert an influence, and the puppet that the non-constant of signal to noise ratio (S/N ratio) occurs is differentiated.
2. with the polychromatic light example.
The wavenumber resolution δ σ of each spectral coverage that the color dispersion-type spectrometer obtains is different, the spectral coverage that is satisfying condition only, after the spectrum that the color dispersion-type spectrometer is obtained carried out conversion with the interfere type principle, its spectral resolution was just consistent with the wavenumber resolution δ σ that requires.
So at spectral coverage to be compared, only needing minimum wavenumber resolution is that the shortwave place satisfies
Condition gets final product.
Referring to Fig. 1, be example with check between color dispersion-type spectrometer and the interference type spectral instrument and demarcation, performing step of the present invention is as follows:
(1.1) obtain the short wavelength light spectral resolution δ σ of the spectroscopic data of color dispersion-type spectrometer
0, from etc. the wavenumber resolution spectroscopic data obtain the maximum optical path difference Δ
Max
(1.2) carry out Fourier transform: reciprocity wavelength resolution spectroscopic data carries out Fourier transform successively, obtains the interferogram of color dispersion-type spectrometer;
(1.3) choose and cut the toe parameter: be about to the maximum optical path difference Δ
MaxParameter as the apodizing function behind the color dispersion-type spectrometer data Fourier transform;
(1.4) carry out rectangle and cut toe: width of dot product is a Δ on the interferogram that color dispersion-type spectrometer Fourier transform obtains
MaxThe rectangle apodizing function;
(1.5) carry out inverse fourier transform: the interferogram of cutting toe through rectangle is carried out inverse fourier transform, obtain the spectrogram of color dispersion-type spectrometer;
(1.6) directly contrast: in the overlapping spectra segment limit, the spectrogram of the spectrogram of color dispersion-type spectrometer and interference type spectral instrument to be compared is carried out the contrast of major parameters such as spectral intensity, position of spectral line, spectral resolution.Promptly check and demarcate.
Have after spectrogram that the color dispersion-type spectrometer of high light spectral resolution obtains becomes interferogram, can freely select identical maximum optical path difference to block according to the maximum optical path difference of interference type spectral instrument to be compared, that is same color dispersion-type spectrometer can check with the interference type imaging spectrometer of different spectral resolutions various different spectral ranges, just should be identical by both spectral ranges of comparison.
Claims (5)
1. the control methods of dissimilar spectrometers, this method comprises following performing step:
(1.1) obtain the spectral resolution δ σ of minimal wave length from equiwavelength's spectral resolution spectrometer data
0, from etc. wavenumber resolution spectrometer data obtain the maximum optical path difference Δ of interference data
Max
(1.2) carry out Fourier transform: reciprocity wave spectrum resolution spectrometer data are carried out Fourier transform successively, obtain the interferogram of the data processing of equiwavelength's spectral resolution spectrometer;
(1.3) choose and cut the toe parameter: the maximum optical path difference Δ
MaxApodizing function parameter as interferogram behind equiwavelength's spectral resolution spectrometer data Fourier transform;
(1.4) carry out rectangle and cut toe: the dot product width is a Δ on the interferogram that equiwavelength's spectral resolution spectrometer data Fourier transform obtains
MaxThe rectangle apodizing function;
(1.5) carry out inverse fourier transform: the interferogram of cutting toe through rectangle is carried out inverse fourier transform, obtain the correction spectrogram of equiwavelength's spectral resolution spectrometer spectroscopic data;
(1.6) compare: in the overlapping spectra segment limit, the spectrogram of the correction spectrogram of reciprocity wave spectrum resolution spectrometer and wave number spectral resolution spectrometer such as to be compared carries out the contrast of spectral intensity, position of spectral line or spectral resolution.
2. the control methods of dissimilar spectrometers according to claim 1 is characterized in that: described equiwavelength's spectral resolution spectrometer to be compared is at the spectral resolution δ of short-wave band σ
0Satisfy
3. the control methods of dissimilar spectrometers according to claim 1 and 2, it is characterized in that: the function of cutting toe behind described equiwavelength's spectral resolution spectrometer Fourier transform to be compared is a rectangular function, and the parameter of this rectangular function is the maximum optical path difference of wave number spectral resolution spectrometer such as to be compared.
4. the control methods of dissimilar spectrometers according to claim 3 is characterized in that: described equiwavelength's spectral resolution spectrometer to be compared is color dispersion-type spectrometer, wedge optical filter type spectrometer or acoustooptic modulation type spectrometer and color dispersion-type imaging spectrometer, wedge optical filter type imaging spectrometer or acoustooptic modulation type imaging spectrometer; Described wave number spectral resolution spectrometer such as to be compared is interference type spectral instrument or interference type imaging spectrometer.
5. the control methods of dissimilar spectrometers according to claim 4, it is characterized in that: described color dispersion-type spectrometer is the color dispersion-type spectrometer of prismatic decomposition mode or grating beam splitting mode, and described color dispersion-type imaging spectrometer is the color dispersion-type imaging spectrometer of prismatic decomposition mode or grating beam splitting mode.
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Cited By (6)
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CN102519597A (en) * | 2011-12-14 | 2012-06-27 | 中国电子科技集团公司第四十一研究所 | Phase correction apodization method for Fourier transform spectrometer |
CN102944309A (en) * | 2012-10-22 | 2013-02-27 | 中国科学院西安光学精密机械研究所 | Equal wavelength resolution spectrum reconstruction method |
CN105043549A (en) * | 2015-05-19 | 2015-11-11 | 中国资源卫星应用中心 | Interference type spectrometer outlying spectrum response attenuation compensating method |
CN105308451A (en) * | 2013-08-05 | 2016-02-03 | 株式会社岛津制作所 | Data processing device for chromatograph and data processing method for chromatograph |
CN105424186A (en) * | 2015-11-04 | 2016-03-23 | 北京航空航天大学 | Spectrum calibration and correction method of light field imaging spectrometer |
CN108593108A (en) * | 2018-05-17 | 2018-09-28 | 深圳市太赫兹科技创新研究院 | Spectrometer |
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JPH10510674A (en) * | 1995-10-03 | 1998-10-13 | フィリップス エレクトロニクス エヌ ベー | Particle optics with fixed diaphragm for monochromatic spectrometer |
CN1124473C (en) * | 2000-10-11 | 2003-10-15 | 中国科学院长春光学精密机械与物理研究所 | Method of utilizing digital interferometer to regulate vacuum ultraviolet interference spectrometer |
DE10205142B4 (en) * | 2002-02-07 | 2004-01-15 | Gesellschaft zur Förderung angewandter Optik, Optoelektronik, Quantenelektronik und Spektroskopie e.V. | Arrangement and method for wavelength calibration in an Echelle spectrometer |
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JP2006266854A (en) * | 2005-03-23 | 2006-10-05 | Shinku Jikkenshitsu:Kk | Quadrupole mass spectrometer with total pressure measuring electrode, and vacuum device using it |
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Cited By (9)
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CN102519597A (en) * | 2011-12-14 | 2012-06-27 | 中国电子科技集团公司第四十一研究所 | Phase correction apodization method for Fourier transform spectrometer |
CN102519597B (en) * | 2011-12-14 | 2013-12-25 | 中国电子科技集团公司第四十一研究所 | Phase correction apodization method for Fourier transform spectrometer |
CN102944309A (en) * | 2012-10-22 | 2013-02-27 | 中国科学院西安光学精密机械研究所 | Equal wavelength resolution spectrum reconstruction method |
CN102944309B (en) * | 2012-10-22 | 2015-05-27 | 中国科学院西安光学精密机械研究所 | Equal wavelength resolution spectrum reconstruction method |
CN105308451A (en) * | 2013-08-05 | 2016-02-03 | 株式会社岛津制作所 | Data processing device for chromatograph and data processing method for chromatograph |
CN105043549A (en) * | 2015-05-19 | 2015-11-11 | 中国资源卫星应用中心 | Interference type spectrometer outlying spectrum response attenuation compensating method |
CN105424186A (en) * | 2015-11-04 | 2016-03-23 | 北京航空航天大学 | Spectrum calibration and correction method of light field imaging spectrometer |
CN108593108A (en) * | 2018-05-17 | 2018-09-28 | 深圳市太赫兹科技创新研究院 | Spectrometer |
WO2019218807A1 (en) * | 2018-05-17 | 2019-11-21 | 深圳市太赫兹科技创新研究院 | Spectrometer |
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