In this study, we utilized tetraphenylpyrrole derivatives (3,4-bis(4-bromophenyl)-1-ethyl-2,5-diphenyl-1H-pyrrole) as the main monomer and different thiophene derivatives as comonomers to synthesize three p-type tetrapenylpyrrole-thiophene based copolymer – PTPP-Th, PTPP-biTh, and PTPP-biOTh for application in bulk-heterojunction polymer solar cells. Recently, a series of tetraphenylpyrrole-based OLEDs has been reported, and it showed that tetraphenylpyrrole derivatives displayed good charge mobility. By introducing tetraphenylpyrrole unit into polymer backbone, the HOMO energy level is lowered, which promises better air stability. Moreover, tetraphenylpyrrole derivatives as BHJ polymer solar cells for light harvesting active layer has not been reported. To adjust and enhance the absorption range of the solar spectrum, our research incorporates thiophene derivatives with different numbers and with/without alkyl chain substituted judiciously for improving hole mobility, coplanarity, conjugated length, and solubility. The concept of using random copolymers is further to enhance the absorbance of solar spectrum. The Tds of these copolymers are all above 300 ℃, which indicate that these copolymers exhibited better thermal properties. Absorption measurements revealed that the harvesting ability has been improved by utilizing random copolymer systems. The photoluminescence emission intensity in thin film are quenched obviously after blended with different ratio of PCBM, which suggest ultrafast photoinduced charge transfer from polymer to PCBM. Electrochemical study present that the HOMO levels of these copolymers are around 5.42 ~ 5.49 eV in comparison with that of 5.29 eV for P3HT, which promised better air stability and a high open circuit voltage (Voc) for OPVs.