ABSTRACT This thesis presents a linear ultrasonic motor with the Chevron clamp stator which is used to propel a push rod forward and backward. Two orthogonal sinusoidal voltages are applied to two sets of piezoelectric elements adhered on the opposite faces of the V-shaped beam stator to excite two coupled flexural vibration modes. Two contact points located on the inner sides of the stator undergo an out-of-plane elliptical trajectory formed by the fundamental in-plane symmetric mode and the second out-of-plane mode. The rod was propelled via friction force, and its moving direction could be switched by phase lag or lead between two sinusoidal inputs. The target flexural modes were fine-tuned to approach a consistent resonant frequency at 29.2 kHz through adjusting dimensions of the stator. A flow chart based on finite-element analysis for modal coupling of the stator is summarized. Resonant frequencies of the stator are sensitive to the value of base screw torque. A robust design for the stator successfully gets rid of the frequency change. A prototype stator made of aluminum alloy and PZT-4 was use to carry out the performance tests. A single stator can achieve the highest linear speed up to 85 mm/s and the maximum thrust 0.539 N for a stainless steel push rod of diameter 8 mm and different lengths under an applied voltage of 300 Vp-p. The stator can be stacked to induce more thrust on the push rod. Keywords: linear ultrasonic motor, V-shaped beam stator, coupled vibration modes, out-of-plane oscillating motion, robust design