Nowadays, cuff-based blood pressure (BP) monitoring is still a wild spread standard method for health care, which including auscultatory and oscillometric. Both of these methods provide high accuracy. Nevertheless, cuff-based BP monitoring methods present disadvantages such as inconvenience, discomfort, and is inappropriate for long time measuring. Moreover, cuff-based BP measurement is not applicable for subjects with stiff artery or atrial fibrillation problems. To achieve the goal of blood pressure measurement without cuff-based method, an innovative BP monitoring method based on pulse transit time (PTT) was proposed in this study. By measuring photoplethysmography (PPG) signals at finger and ear simultaneously, the issues of cuff-based BP measurement mentioned above could be improved. Thus, two PPG pods with LED and photodetector which required simply contact to skin surface were utilized to replace the inflated cuff. With the two different positioned PPG pods, the PTT could be calculated from the PPG waveforms. Combined with adequate BP data, a simple continuous BP measurement via successive PPG will be fulfilled. For cuff-less BP monitoring, PTT is a wild used parameter. In traditional, the PTT was defined as the time difference between the R-peak of an electrocardiogram (ECG) and the foot point of PPG waveform which represents the moment when blood flow is rushing out of aortic valve. However, the ECG signal is affected by voltage interference, sweat and the state of patches easily which could make the instability of the PTT calculation based on ECG and PPG signals. In this study, the traditional PTT calculation was replaced by detecting two different positioned PPG waveforms at the same time. Several researches have shown the high correlation between PTT and BP, both of systolic blood pressure (SBP), diastolic blood pressure (DBP) and pulse pressure (PP). The BP regression model based on PWV or PTT was established for investigating the effect of heart beat force on BP, that is PP. Therefore, PP is the target of regression in this study. In order to calculate PTT for PP regression model, this study built a system for measuring ear and finger PPG signals at the same time and validated the system by a commercial instrument to ensure the accuracy of measurement. Before PTT calculation, this study developed an algorithm for PPG feature extraction on both typical and untypical PPG waveforms, then defined PTT as the time difference between max slope points on two PPG signals. Besides adapting PTT as the parameter for PP regression model, more parameters were chosen from artery mechanics model which was based on fluid and material mechanics theory and with appropriate assumptions. Here introduced the slope on PPG waveform between characteristic points as the regression parameter which was corresponding to flow rate in artery. Furthermore, this study analyzed the effect and weighting of each parameter in PP regression model to validate the artery mechanics model. Finally, by comparing with the existed PP regression models, the new PP regression model which was proposed in this study by introducing, and showed great improvement on R2 performance either in the results of single subject or multiple subjects regression.