Title :
Designing a piezoelectric stack for incus driving actuator using finite element method
Author :
Liu, Houguang ; Tian, Jiabin ; Rao, Zhushi
Author_Institution :
State Key Lab. of Mech. Syst. & Vibration, Shanghai Jiao Tong Univ., Shanghai, China
Abstract :
Design of a piezoelectric stack for incus driving actuator characterized by small size, low power consumption and broad frequency bandwidth for a middle ear implant was presented in this paper. To aid the design process, a coupling biomechanics model of the human middle ear and the piezoelectric stack actuator was constructed. This model was build based on a complete set of computerized tomography section images of a healthy volunteer´s left ear by reverse engineering technology. The result shows that the stapes footplate displacement stimulated by the designed piezo-stack actuator´s excitation at 10.5 V rms was equivalent to that from acoustic stimulation at 90 dB SPL, which is adequate stimulation to the ossicular chain. The corresponding power consumption is 0.03 mW per volt of excitation at 1 kHz, which is low enough for the actuator to be used in a middle ear implant.
Keywords :
biomechanics; cochlear implants; computerised tomography; finite element analysis; low-power electronics; piezoelectric actuators; prosthetic power supplies; acoustic stimulation; biomechanics model; broad frequency bandwidth; computerized tomography section images; finite element method; footplate displacement; human middle ear; incus driving actuator; low power consumption; middle ear implant; ossicular chain; piezoelectric stack; reverse engineering technology; Actuators; Auditory system; Biological system modeling; Ear; Finite element methods; Humans; Predictive models; finite element method; incus driving; middle ear implant; piezoelectric stack;
Conference_Titel :
Biomedical Engineering and Informatics (BMEI), 2010 3rd International Conference on
Conference_Location :
Yantai
Print_ISBN :
978-1-4244-6495-1
DOI :
10.1109/BMEI.2010.5639369
