The most popular color generation of TFT-LCDs has been based on pigment dispersed (PD) color filters (CFs) built in the LCD panel to produce sub-pixel-red (R), -green (G), and –blue (B) colors from a backlight system attached onto the panel. Experimental results showed that, by placing such PDCF plate between cross polarizers, additional light leakage occurred due to the change of the linearly polarized input light into elliptically polarized output light. We call this effect as the depolarization-induced degradation of contrast ratio (DID-CR) due to the PDCF. The DID-CR depends on the particle size of PDCF. So far, there have been no prior publications to explain the mechanism of DID-CR of the PDCF. In this thesis, we suggest two optical models: birefringent effect (BRE) and Mie scattering effect (MSE) caused by PDCF particles to explain the phenomenon of DID-CR. In the BRE model, we use Jones matrix method to calculate the DID effect through a PDCF of fixed thickness but composed of multi-layer pigment-particles of different sizes. Using the BRE model, we have confirmed the occurrence of DID-CR that is proportional to the particle sizes within the PDCF plate consistent with published results. In our MSE model, we have assumed that the PDCF particles are optically isotropic and the effect of DID-CR disappears for forward-scattered lights independent of particles sizes. For fixed particle size, the effect of DID-CR increases with increasing oblique-scattered angles and the scattered intensity within the same solid angle increases as the particle size decreases. The MSE model at this moment of development is unable to produce suitable numerical results to compare with the experimental results that the effect of DID-CR is more severe with larger particles and much reduced with smaller particles within the PDCF layer.