The purpose of this thesis is to develop a wearable blood pressure device based on a flexible membrane sensor. In order to achieve long-term continuous measurement and attach to the epidermis, the sensor material must be biocompatible and flexible. The piezoelectric polymer P(VDF-TrFE) not only is biocompatible and flexible, it also has an excellent chemical resistance. The piezoelectric membrane was fabricated by electrospinning with a high-speed drum collector, the microfibers can have a high degree of alignment followed by annealing and corona charging process to enhance piezoelectric property. Since the membrane was built by microfibers, there are many void in the membrane. This micro-structure makes the membrane have both piezoelectric and electrostatic effect. In this study, specific surface electrodes are designed for P(VDF-TrFE) membrane and 4-point bending test was used to perform small strain measurement. Experimental results show that using 10 mm by 10 mm surface electrodes, the sensitivity for fibers in parallel with bending was 7.4 to 19.3 higher than the one in perpendicular with bending direction. For the condition of having bending direction and the fibers direction are in parallel, the piezoelectric effect and the electrostatic effect contribute to the sensitivity of 68% and 32%, respectively; while in the condition of vertically aligned, the contribution of electrostatic signal is opposite to piezoelectric signal in -43%. The optimal condition is to align the sensor in parallel with bending direction, the sensitivity can reach 1.06 pA/με. In addition, the results of using 2 mm by 10 mm electrodes show that having fibers align with the bending direction, the ratio of directionality is 6.6(before immerse IPA) and 12.6(after immerse IPA). In human tests, we study the ability of different sensors to minimize the influence of body movement and its sensitivity to arterial-induced skin deformation. Experimental results show that using the sensor with fibers align with blood vessel on the wrist has the highest performance. Furthermore, complete pulse waveforms can be measured among different subjects, and the output of the sensor has characteristics corresponding to the PPG signal and the blood flow signal. The peaks caused by ventricular contraction and the reflected wave of the lower body can also be characterized. The sensor output is also compared to the heart rate of the PPG signal, and the difference is less than 0.09 seconds.