In this thesis, a gradient grating period-guided mode resonance filter (GGP-GMRF) spectrometer was designed and fabricated. The GGP-GMRF spectrometer is composed of a guided-mode resonance (GMR) filter with gradient grating period and a linear photodetector. The impact of the resonant line width of GMR on the spectral resolution was investigated. The GGP-GMR filter is a one-dimensional periodic surface relief structure consisting of a plastic substrate, a UV-curable polymer with a surface relief pattern and a high-refractive-index TiO2 film. At normal incidence, a specific wavelength of light excites the resonance of GMR filter structure and be reflected. The resonant wavelegnths of GGP-GMRF for both TE- and TM- polarized illumination show linear relationship with the spatial locations. Furthermore, the full width half maximum of TM mode is narrower than TE mode. To compare the spectral resolving capability of the designed spectrometer from TE- (broad line width) and TM-polarized modes (narrow line width), different kinds of light sources were used as illumination source, including monochromatic light, red LED, a linear variable filter with broadband light source and HG-1 calibration source. The results indicate that by operating at TM mode (narrower resonant linewidth), more accurate and higher spectral resolution can be obtained.