Cascaded, self-calibrated, single-pixel infrared hadamard transform spectrometer

The invention claimed is: 1 . An infrared spectrometer comprising: a first single pixel detector sensitive to infrared light in a first spectral range; an entrance slit for receiving an infrared light signal; a moveable encoding mask disposed between the entrance slit and the first single pixel detector for encoding based multiplexing, the moveable encoding mask comprising at least three adjacent coding sections along an encoding moving direction thereof, each coding section comprising the same coding pattern in a cyclic manner such that the last encoding step of one section is the same as the first encoding step in the next section; a dispersion and imaging optics disposed between the entrance slit and the moveable encoding mask for dispersing the infrared signal and for imaging the dispersed infrared signal onto the moveable encoding mask; a collection optics disposed between the moveable encoding mask and the first single pixel detector for collecting an encoding based multiplexed version of the infrared signal onto the first single pixel photodetector; and a band selection optics for selectively allowing only one of at least first and second bands within the first spectral range to be imaged onto respective ones of the coding sections excluding a first coding section along the encoding moving direction of the moveable encoding mask, in a starting position of the moveable encoding mask. 2 . The spectrometer of claim 1 , comprising a second single pixel detector sensitive to a wavelength of a reference laser signal, wherein the dispersion and imaging optics is configured to image the reference laser signal received via the entrance slit onto the moveable encoding mask and the collection optics is configured for collecting the reference laser signal comprised in the encoding based multiplexed version of the infrared signal onto the second single pixel detector for calibration of a recovered spectrum of interest within the first spectral range in the first single pixel detector. 3 . The spectrometer of claim 2 , wherein the dispersion and imaging optics comprises a first grating for generating different order signals from the reference laser signal for imaging onto respective different encoding sections of the moveable encoding mask, and the collection optics comprises a second grating for re-generating the reference laser signal at the wavelength to which the second single detector is sensitive, and preferably wherein the dispersion and imaging optics comprises a blocking element for selectively allowing only one of the different order signals to be imaged onto the moveable encoding mask. 4 . The spectrometer of claim 1 , wherein the moveable encoding mask comprises a movement calibration pattern outside the at least three coding sections, and the spectrometer further comprises an encoder module coupled to the moveable encoding mask for generating a varying output signal based on movement of the movement calibration pattern relative to the encoder module. 5 . The spectrometer of claim 4 , wherein the movement calibration pattern comprises slits or pixels, and the encoding module generates an output signal representative of movements in steps of single slits or pixels of the encoding sections. 6 . The spectrometer of claim 5 , wherein the slits or pixels have twice a width of slits or pixels of the encoding sections, and the encoding module generates a two phase output signal representative of movements in steps of single slits or pixels of the encoding sections or wherein the slits or pixels have the same width of slits or pixels of the encoding sections, and the encoding module generates a single phase output signal representative of movements in steps of single slits or pixels of the encoding sections. 7 . The spectrometer of claim 1 , comprising a processor for recovery of the spectrum of interest within the first spectral range in the first single pixel detector, and preferably wherein the encoding sections comprise an S-matrix pattern, and the processor is configured for inverse Hadamard transform for the recovery of the spectrum of interest within the first spectral range in the first single pixel detector. 8 . A method of performing infrared spectrometry using the infrared spectrometer of claim 1 , comprising the steps of: providing the first single pixel detector sensitive to infrared light in the first spectral range; providing the entrance slit for receiving the infrared light signal; disposing the moveable encoding mask between the entrance slit and the first single pixel detector for encoding based multiplexing, the moveable encoding mask comprising at least three adjacent coding sections along the encoding moving direction thereof, each coding section comprising the same coding pattern in the cyclic manner such that the last encoding step of one encoding section is the same as the first encoding step in the next encoding section step; disposing the dispersion and imaging optics between the entrance slit and the moveable encoding mask for dispersing the infrared signal and for imaging the dispersed infrared signal onto the moveable encoding mask; disposing the collection optics between the moveable encoding mask and the first single pixel detector for collecting an encoding based multiplexed version of the infrared signal onto the first single pixel photodetector; selectively allowing only one of at least first and second bands within the first spectral range to be imaged onto respective ones of the coding sections excluding the first coding section along the encoding moving direction of the moveable encoding mask, in the starting position of the moveable encoding mask; and moving the moveable encoding mask in the encoding moving direction for the encoding based multiplexing. 9 . The method of claim 8 , comprising providing a second single pixel detector sensitive to a wavelength of a reference laser signal, and configuring the dispersion and imaging optics to image the reference laser signal received via the entrance slit onto the moveable encoding mask and configuring the collection optics to collect the reference laser signal comprised in the encoding based multiplexed version of the infrared signal onto the second single pixel detector for calibration of a recovered spectrum of interest within the first spectral range in the first single pixel detector. 10 . The method of claim 9 , wherein the dispersion and imaging optics comprises a first grating for generating different order signals from the reference laser signal for imaging onto respective different encoding sections of the moveable encoding mask, and the collection optics comprises a second grating for re-generating the reference laser signal at the wavelength to which the second single detector is sensitive, and preferably wherein the dispersion and imaging optics comprises a blocking element and the method comprises selectively allowing only one of the different order signals to be imaged onto the moveable encoding mask. 11 . The method of claim 8 , wherein the moveable encoding mask comprises a movement calibration pattern outside the at least three coding sections, and the method further comprises using an encoder module coupled to the moveable encoding mask for generating a varying output signal based on movement of the movement calibration pattern relative to the encoder module. 12 . The method of claim 11 , wherein the movement calibration pattern comprises slits or pixels, and the encoding module generates an output signal representative of movements in steps of single slits or pixels of the encoding sections, and preferably wherein the slits or pixels have twice a width of s