Spectroscopic analysis apparatus, spectroscopic analysis method, steel strip production method, and steel strip quality assurance method

The invention claimed is: 1. A spectroscopic analysis apparatus comprising: a light projecting device configured to project infrared light to a measurement target object; a light receiving device configured to receive, as reflected light, the infrared light reflected by a surface of the measurement target object; and an output device configured to calculate either or both of a composition and a composition ratio of the surface of the measurement target object using the reflected light received by the light receiving device, wherein the light receiving device includes: a separator configured to separate the reflected light into s-polarized light and p-polarized light; a first detector for s-polarized light configured to detect s-polarized light obtained through the separation by the separator and output an electric signal indicating an intensity of the s-polarized light to the output device; and a second detector for p-polarized light configured to detect p-polarized light obtained through the separation by the separator and output an electric signal indicating an intensity of the p-polarized light to the output device; and the output device is configured to: calculate an absorbance based on a ratio between the intensities of the s-polarized light and the p-polarized light using the electric signals output from the detector for s-polarized light and the detector for p-polarized light; and calculate either or both of the composition and the composition ratio of the surface of the measurement target object using an intensity of the absorbance at any desired wavenumber. 2. The spectroscopic analysis apparatus according to claim 1 , further comprising a distance measuring device configured to measure a distance between a position irradiated with the infrared light on the measurement target object and a spectroscopic measurement apparatus, wherein the output device corrects the absorbance in accordance with values measured by the distance measuring device. 3. A spectroscopic analysis method, comprising: projecting infrared light to a measurement target object; receiving, as reflected light, the infrared light reflected by a surface of the measurement target object; and calculating either or both of a composition and a composition ratio of the surface of the measurement target object using the reflected light received at the receiving, wherein the receiving includes: separating the reflected light into s-polarized light and p-polarized light; first detecting s-polarized light obtained through the separating, and outputting an electric signal that indicates an intensity of the detected s-polarized light; and second detecting p-polarized light obtained through the separating, and outputting an electric signal that indicates an intensity of the detected p-polarized light, the first detecting and the second detecting being performed in any order; and the calculating includes: calculating an absorbance based on a ratio between the intensities of the s-polarized light and the p-polarized light using the electric signals output at the detecting s-polarized light and at the detecting p-polarized light; and calculating either or both of the composition and the composition ratio of the surface of the measurement target object using an intensity of the absorbance at any desired wavenumber. 4. A steel strip production method, comprising: producing a steel strip; and analyzing either or both of a composition and a composition ratio of a surface of the steel strip produced at the producing using the spectroscopic analysis method according to claim 3 . 5. A method of assuring steel strip quality, comprising: analyzing either or both of a composition and a composition ratio of a surface of a steel strip using the spectroscopic analysis method according to claim 3 ; and conducting quality assurance of the steel strip based on an analysis result obtained at the analyzing.