Arterial stiffness is an important predictor to use when diagnosing cardiovascular disease. Recently, Pulse transit time and ankle branchial pressure index has been clinically identified as an index for evaluation of arteriosclerosis. Among these, pulse transit time is most often used in clinical medicine. However, the indirect method does not evaluate the actual material properties of arterial walls precisely, which may lead to misdiagnosis. Therefore, just considering pulse transit time is not suitable for evaluating arterial elasticity. In this research, we used a guided wave dispersion model to estimate the elastic properties of arterial phantoms. The theoretical assumptions were composed of a thin layer plate, the substrate layer and water-like fluid layer to simulate the blood vessels. In experimental setup, A fast air-puff valves was used to create a repetitive 80Hz to 200Hz low-frequency air-puff excitation to excite the guided wave propagation in the pipe wall. Polymer pipes were embedded in gelatin to simulate skin tissue and arteries. The system used a fiber-based laser doppler velocimetry to measure the velocity of the traveling waves on the pipe walls. Moreover, the probe was mounted on a linear translation stage and measuring the traveling waves velocity at multiple points. Then, the wave velocities were analyzed by the phase difference between the signal of different positions. The elastic property of the pipe was used to calculate the guided wave velocity by fitting a guided wave dispersion model. To verify the accuracy of this method, an atomic force microscope was used to measure the real elastic properties of the pipe and then compared to the proposed method. The prediction results of the silicon rubber pipe and latex pipe, the average error of the elastic modulus was found to be 8.25% and 7.14%. The results show good similarity and consistency of the two methods. And using the method to verify feasibility and accuracy of the elastic properties of radial arterial walls in vivo. In conclusion, we propose a novel technique for the assessment of mechanical properties of arterial walls in-vitro with high accuracy. Simulated experiments were performed to validate the proposed method. Our new proposed technique has been efficient to diagnose cardiovascular diseases more accurately for both home health care and for wearable devices.