Fourier transform spectrometer using a multielement liquid crystal display
First Claim
1. A Fourier transform spectrometer, which comprises in combination:
- (a) a polychromatic light source;
(b) means for dispersing the light from the light source into spectral components;
(c) a first polarizer intercepting the spectrally dispersed light and providing a chosen angle of polarization thereto;
(d) a multiple-element polarizing device intercepting the spectrally dispersed and polarized light, each element thereof being responsive to an applied voltage which voltage determines the amount of polarization rotation of that element, for encoding each spectral component with a different time-varying dependence of polarization rotation for that spectral component;
(e) a second polarizer for intercepting the time-varying polarization rotation spectral components and generating therefrom a time-varying intensity for each spectral component;
(f) a time-varying voltage generator for each element of said multiple element polarization device;
(g) means for recombining the intensity modulated, dispersed light into a single light beam;
(h) a beam splitter for dividing the intensity modulated collimated light into a sample light beam and a reference light beam;
(i) means for introducing a sample into the sample light beam and for permitting light to exit the sample after passing therethrough;
(j) means for detecting the light exiting from the sample and the reference light beam; and
(k) means for performing a Fourier transform of the detected light exiting from the sample cell and the reference light beam, whereby a spectrum of the sample is obtained.
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Abstract
Fourier transform spectrometer using a multielement liquid crystal display. A ferroelectric liquid crystal mask is used as an optical encoder for a solid-state Fourier transform spectrometer. A 1×64 element array was striped and used as a 1×4 element device. The device intersected dispersed radiation and encoded each spectral component thereof with a carrier signal by applying half-wave potentials to each of the four striped (1×16) liquid crystal elements which varied the transmitted amplitude of the light from 0.03% to 28% of full scale. The light was spectrally recombined and imaged onto a photomultiplier and the resulting carrier frequencies (and their amplitudes) detected by Fourier transformation of the time-varying signal. Spectra of colored-glass filters were taken to demonstrate the spectrometer.
105 Citations
18 Claims
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1. A Fourier transform spectrometer, which comprises in combination:
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(a) a polychromatic light source; (b) means for dispersing the light from the light source into spectral components; (c) a first polarizer intercepting the spectrally dispersed light and providing a chosen angle of polarization thereto; (d) a multiple-element polarizing device intercepting the spectrally dispersed and polarized light, each element thereof being responsive to an applied voltage which voltage determines the amount of polarization rotation of that element, for encoding each spectral component with a different time-varying dependence of polarization rotation for that spectral component; (e) a second polarizer for intercepting the time-varying polarization rotation spectral components and generating therefrom a time-varying intensity for each spectral component; (f) a time-varying voltage generator for each element of said multiple element polarization device; (g) means for recombining the intensity modulated, dispersed light into a single light beam; (h) a beam splitter for dividing the intensity modulated collimated light into a sample light beam and a reference light beam; (i) means for introducing a sample into the sample light beam and for permitting light to exit the sample after passing therethrough; (j) means for detecting the light exiting from the sample and the reference light beam; and (k) means for performing a Fourier transform of the detected light exiting from the sample cell and the reference light beam, whereby a spectrum of the sample is obtained. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
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10. A method for spectroscopically analyzing a sample, which comprises the steps of:
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a. generating polychromatic light; b. dispersing the polychromatic light into spectral components; c. providing a chosen angle of polarization to the spectral light components; d. directing the polarized spectral light components into a multiple-element polarizing device, each element thereof encoding a spectral component with a different time-varying dependence of polarization rotation for that spectral component; e. generating a time-varying intensity modulation for each spectral component; f. recombining the intensity modulated, dispersed light into a single light beam; g. dividing the intensity modulated collimated light into a sample light beam and a reference light beam; h. permitting the sample light beam to pass through the sample; i. detecting the light exiting from the sample and light from the reference light beam; and j. performing a Fourier transform of the detected light exiting from the sample and the reference light beam, whereby a spectrum of the sample is obtained.
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11. A Fourier transform spectrometer for measuring emission from a radiant sample, which comprises in combination:
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a. means for dispersing the light from the radiant sample source into spectral components; b. a first polarizer intercepting the spectrally dispersed light and providing a chosen angle of polarization thereto; c. a multiple-element polarizing device intercepting the spectrally dispersed and polarized light, each element thereof being responsive to an applied voltage which voltage determines the amount of polarization rotation of that element, for encoding each spectral component with a different time-varying dependence of polarization rotation for that spectral component; d. a second polarizer for intercepting the time-varying polarization rotation spectral components and generating therefrom a time-varying intensity for each spectral component; e. a time-varying voltage generator for each element of said multiple element polarization device; f. means for recombining the intensity modulated, dispersed light into a single light beam; g. means for detecting the light in the single light beam; and h. means for performing a Fourier transform of the detected light, whereby a spectrum of the radiant sample is obtained. - View Dependent Claims (12, 13, 14, 15, 16, 17, 18)
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Specification