Title :
Signal conditioning of carbon nanotube thin film loudspeakers
Author :
Hall, A. ; Gaston, J. ; Wolde, W. ; Baker, E. ; Okada, M. ; YuHuang Wang ; Karna, S.
Author_Institution :
Vehicle Technol. Directorate, US Army Res. Lab., Aberdeen Proving Ground, MD, USA
Abstract :
Super-aligned carbon nanotube (CNT) thin films offer the capability to be placed into compact lightweight sound sources for active noise control, loudspeaker, or other acoustic applications. The super-aligned CNT films generate thermoacoustically induced oscillations to generate sound. This occurs through the use of a dynamic signal, such as applying an alternating current in the audio frequency range to the thin film. This mechanism is carried out through joule heating which heats the air above the surface, thereby producing sound waves from periodic air vibration. Here, we report an investigation of the sound pressure and thermal properties of advanced carbon nanotube thin films with an emphasis to address the signal distortion issue.
Keywords :
acoustic distortion; acoustic signal processing; acoustic waves; active noise control; carbon nanotubes; loudspeakers; thin film devices; CNT thin film loudspeaker; acoustic application; active noise control; compact lightweight sound source; dynamic signal; joule heating; periodic air vibration; signal distortion; sound generation; sound pressure; sound wave production; super-aligned carbon nanotube thin film loudspeaker signal conditioning; thermal property; thermoacoustically induced oscillation generation; Carbon nanotubes; Films; Harmonic analysis; Heating; Loudspeakers; Power harmonic filters; Pulse width modulation; Carbon Nanotube thin film loudspeaker; Thermophone;
Conference_Titel :
Nanotechnology (IEEE-NANO), 2014 IEEE 14th International Conference on
Conference_Location :
Toronto, ON
DOI :
10.1109/NANO.2014.6968142
