This thesis mainlu presents an animation of the sporangial motion for making bionic tail actuators of flapping micro-air-vehicles(FMAVs) regarding energy saving. A SUS-304 steel foil of 40μm thick is used as the working substrate. The actuation area of 40-50 comb-shaped cantilevers is designed to have the maximum actuating angle change about several degrees. Nd-YAG laser machining with air cooling and water cooling respectively are performed to cut off the surface tension-driven actuators. Surface modification including parylene coating and oxygen plasma treatment are added to enlarge the actuation stroke angles up to 10˚-12˚ for practical usage in flight direction control. Secondly, the payload modification of the FMAVs is also addressed. The added payload is for the make up of the bionic tail actuator. The design method is to assign the center of gravity in the middle of the FMAV. The tail area is so close to the flapping wing area as to generate the approximately equivalent lift to the flapping lift. The flight test of the new FMAV with wingspan of 25.5cm verifies the above design.