Ferroelectric materials have been widely recognized as one of important smart materials due to their excellent dielectric and piezoelectric behavior, and are therefore often used in actuator and sensor applications. It has been widely known that the abnormally large dielectric and piezoelectric behavior can be observed by forming MPB (morphotropic phase boundary) due to chemical alloying in certain conventional lead-based ferroelectrics. The explanations vary due to different observations of experiment. One of the important observations is the appearance of fine scales of laminar domain patterns as the composition approaches MPB (Wang et al. 2003; Wang 2006; Schonau et al. 2007; Wang 2007). As a result, the convention models based on single domain state for explaining the enhancement of piezoelectricity are questionable. Here, we propose a model based on energy minimizing laminated domain pattern for studying the effective dielectric and piezoelectric properties at composition near MPB. It is found that the effective coefficients are not equivalent to the simple volume average of the distinct domain states. The results are consistent to those base on micromechanics calculations when the applied field is small. In addition, the effective dielectric and longitude piezoelectric coefficients at the poling direction are much larger than those calculated based on the single domain state.