In this thesis, we intended to modify the actuating structure of a traditional deformable mirror which was actuated by an electrode-array. We developed a new smart composite material which could use optical illumination to modulate the spatially distributed actuating forces. The smart composite material is composed of photoconductive material TiOPc (Titanyl Phthalocyanine) and piezoelectric material PZT (Lead Zirconate Titanate) to perform Opto-Piezo modulation. More specifically, spatial modulation in this smart composite is done by using a light field instead of an electrical field to modulate the spatial distribution of the force field created. To enhance the effect of a light field modulated force field, the electrical impedance of TiOPc/copolymer thin film and piezoelectric lamina must match. The electrical impedance of TiOPc thin film was measured by Agilent 4294A Precision Impedance Analyzer and an equivalent circuit model was established. According to the experimental results of the measured electrical impedance, we built the relationship between the parameters of thin film process and the equivalent R-C value in the equivalent circuit model. Further experiments were performed to establish the relationship between light intensity and the R-C value. An actuator equation was also developed for the spatially modulated TiOPc/PZT actuator. ESPI (Electronic Speckle Pattern Interferometer) was then introduced to test the ability of the spatially modulated TiOPc/PZT actuator. The experimental results confirmed the ability of spatial modulation. Furthermore, we used CODE V to perform surface fitting of Zernike polynomial. The spatial modulation by light achieved was identified to be able to compensate third-order aberration such as field curvature and astigmatism.