In this study, a light-transmissible spectroscopic solar concentrator is proposed. Using slanted trapezoidal grating and layered grating with different periods are designed as the first and second transmissive-deflection components respectively. The first component deflects the incident sunlight with wavelengths of 400-600 nm at a large angle into the Tapered Light Guide Plate (TLGP) below, and then the light propagates to the TLGP end face through internal total reflection. The second component deflects the incident sunlight with wavelength of 600-900 nm that passes the first component at a large angle into the TLGP below, and then the light propagates to the TLGP end face through internal total reflection. Different types of grating structures are optimized by Rigorous Coupled-Wave Analysis (RCWA) to maximize the first-order diffraction efficiency. After optimization, the diffraction efficiencies of the first and second gratings of the best model are 83% and 88%, respectively. Finally, an additional optical element such as a compound parabolic concentrator (CPC) is attached to the end of the light guide plate to further increase the geometric concentration ratio of the output light up to 7.6. Assuming that the model is located in Taipei at 25.05 degrees north latitude and is placed tilting to the south for tracing the sun from 8:00 to 16:00 every day by uniaxial rotation, for the solar spectrum of 400~900 nm, the average annual efficiency is 70%, and the overall transmittance for ambient diffuse light is about 27%.