Cardiovascular disease (CVD) is one of the fatal diseases in Taiwan, and it may be caused by hypertension. Therefore, blood pressure monitoring is an important task to prevent CVD. The most common way to measure blood pressure is cuff-based sphygmomanometer, the merits of the method are convenient and non-invasive. However, it can only measure systolic and diastolic pressure. On the other hand, a pressure wire catheter is an invasive approach for continuous pressure measurements. However, it is invasive so it can only be performed by clinical physicians. To evaluate blood pressure non-invasively, we first proposed the use of pulse wave velocity (PWV) to evaluate the relative blood pressure. With the relative blood pressure, the absolute pressure can then be measured. To demonstrate this approach, carotid-mimicking vessel phantoms with a pulsatile pump and ultrafast ultrasound imaging was employed to estimate the PWV. Results of relative blood pressures in phantoms and humans measured by the proposed method show less than 15% and 20% respectively errors as compared with the relative pressures measured by a pressure sensor and a sphygmomanometer. Besides, results of absolute blood pressure measurements show up to 50% errors. The high errors can be explained by an error propagation analysis from the shear modulus estimation to the absolute pressure measurements. Specifically, a 1 kPa error in shear modulus results in 21 mmHg error of absolute pressure. In addition, results of shear modulus at different pressures (25, 40, 80 and 115 mmHg) measured by shear wave elasticity imaging show the positively correlated relationship between the blood pressure and the shear modulus. How to reduce errors in absolute blood pressure measurements is an important task for future work.