Solid-state spectrometer

What is claimed is: 1 . A sensing system configured to analyze constituents in a gas flow, the sensing system comprising: a light emitter configured to emit at least one beam of light; a sample chamber adapted for supporting interaction of the beam of light received from the light emitter with the gas flow; a first light detector; a second light detector; and a beam splitter comprising a first plurality of reflecting surfaces and a second plurality of reflecting surfaces, wherein the first and the second plurality of reflecting surfaces form a plurality of grooves, and a reflecting surface of the plurality of reflecting surfaces has a parabolic shape. 2 . The sensing system according to claims 1 , wherein the first plurality of reflecting surfaces are configured to redirect and focus a first portion of the beam of light transmitted through the sample chamber on the first light detector; and the second plurality of reflecting surfaces are configured to redirect and focus a second portion of the beam of light transmitted through the sample chamber on the second light detector. 3 . The sensing system according to claim 1 , further comprising a collimator configured to transform the beam of light generated by the said light emitter to a collimated beam of light passing through the said sample chamber. 4 . The sensing system according to claim 2 , wherein the sensing system is configured to generate a differential signal using a first signal received from the first light detector and a second signal received from the second light detector. 5 . The sensing system according to claim 4 , wherein the differential signal is a linear or non-linear function of the first signal and the second signal, and wherein the differential signal is usable for estimating a concentration of a target gas molecule in the sample chamber. 6 . The sensing system according to claim 5 , wherein the light emitter is configured to emit light within a wavelength interval including at least one absorption wavelength band of the target gas molecule. 7 . The sensing system according to claim 1 , wherein the light emitter is a thermal emitter. 8 . The sensing system according to claim 5 , wherein the first light detector is covered by a first filter, wherein the first filter transmits light having wavelengths within at least one of absorption wavelength bands of the target gas molecule. 9 . The sensing system according to claim 8 , wherein the target gas molecule is carbon dioxide. 10 . The sensing system according to claim 9 , wherein the absorption wavelength band of the target gas molecule is located near 4.2 micrometer. 11 . The sensing system according to claim 5 , wherein the second light detector is covered by a second filter, wherein the second filter transmits light having wavelengths not overlapping with any of absorption wavelength bands of the target gas molecule. 12 . The sensing system according to 2 , wherein an area of the illuminated region on each light detector by the first or the second portion of beam of light transmitted through the sample chamber, is smaller than a sensitive area of the light detector. 13 . The sensing system according to claims 1 , further comprising an airway adapter wherein the airway adapter comprises: a gas entrance port and a gas exit port; the sample chamber, wherein the sample chamber is configured to support gas flow along a longitudinal direction from the said entrance port to the said exit port; an entrance window; and an exit window to allow transmission of light through the sample chamber along a transverse direction perpendicular to the said longitudinal direction. 14 . An spectrometer configured to analyze constituents in a gas flow, the spectrometer comprising: a light emitter configured to emit at least one beam of light; a sample chamber adapted for supporting interaction of the beam of light received from the light emitter with the gas flow; a first light detector; a second light detector; and a beam splitter configured to: divide the beam of light transmitted though the sample chamber into a first and a second beam of light; focus the first beam of light on the first light detector; and focus the second beam of light on the second light detector. 15 . The spectrometer according to claim 14 , wherein the spectrometer is configured to generate a differential signal using a first signal received from the first light detector and a second signal received from the second light detector, wherein the differential signal is usable for estimating a concentration of a target gas molecule in the sample chamber. 16 . The spectrometer according to claim 14 , further comprising an off-axis parabolic mirror configured to transform the beam of light generated by the said light emitter to a collimated beam of light passing through the said sample chamber before being divided by the beam splitter. 17 . The spectrometer according to claim 14 , wherein the beam splitter, is a segmented reflective beam splitter. 18 . The spectrometer according to claim 17 , wherein the segmented beam splitter, is a concave segmented reflective beam splitter comprising two sets of elliptic parabolic reflecting surfaces. 19 . The spectrometer according to claim 15 , wherein in the absence of the target gas molecule in the sample chamber, a difference between the power carried by the first beam of light and the power carried by the second beam of light is less than 5% of the total power carried by the beam of light emitted by the light emitter. 20 . The spectrometer system according to claim 15 , wherein the target gas molecule is carbon dioxide molecule.