The thesis proposes a piezoelectric device capable of harvesting energy form rotary magnetic plucking dynamics. It is intended for self-powering sensors used in the health monitoring of smart bearings. The device consists of a piezoelectric cantilever beam fixed on the outer ring of a ball-bearing structure and attached to the standard energy harvesting circuit. A tip magnet is excited along the radial direction by a rotating magnet. Energy is therefore harvested by vibration due to non-contact magnetic plucking. A theoretical framework is developed based on the analysis of magnetic interaction and the use of the Fourier technique. There are several observations drawn from the proposed theory. First, the smaller ratio of magnetic distance to the radius revolution gives the more stable rotary frequency response. Second, the choice of high resonance of a piezoelectric oscillator gives dense rotary frequency response. Third, the reduction of ripples in rotary frequency response can be achieved by requiring larger mechanical damping. These observations are subsequently confirmed by experiment. Finally, the effect of the noise induced by the random vibration of the outer ring of a ball-bearing structure is studied. It is found that the ripples in the rotary frequency response are reduced at the significant cost of harvested power.