SBIR-STTR Award

Acoustic survey is now performed using hand-held devices once every two months on the international space station (ISS). It takes quite a lot of precious crew time and the sporadic monitoring program is not adequate. This Phase I proposal is concerned with developing an automated sound level and noise exposure monitoring system running on a ZigBee-compliant wireless sensor network. In the proposed research, we will focus on a preliminary design of the monitoring terminal that integrates the functionalities of microphone, data sampling, and signal processing along with data communication through a ZigBee wireless channel. Sufficient compliance of the developed sound level meter and noise dosimeter with the related ANSI standards will be tested and demonstrated. This plan takes advantage of our broad knowledge in acoustic signal processing and ZigBee wireless sensor network, and will benefit from our experience and skills with the development of embedded digital signal processing systems using either FPGA (field programmable gate array) or DSP (digital signal processor). The Phase I effort will provide a foundation for prototype design to be conducted in Phase II.

The International Space Station (ISS) needs to keep quiet to maintain a healthy and habitable environment in which crewmembers can perform long-term and uninterrupted scientific research under microgravity conditions. Acoustic survey is now performed once every two months using hand-held devices at 60 locations on the ISS. It takes a significant amount of precious crew time and the sporadic monitoring program is not adequate. NASA has defined a need for an automated, continuous acoustic monitoring system that is efficient in power consumption (long battery life), accurate, highly integrated, wireless connected, scalable, small and lightweight. WeVoice Inc.\ proposed to develop a ZigBee-based wireless sensor network for acoustic monitoring to meet the challenges. During Phase I of this projects, three essential capabilities were developed, tested, and validated: * The design of a data collection subsystem that integrates measurement microphones and the feasibility of using the state-of-the-art MEMS microphones. * The development of accurate and computationally efficient signal processing algorithms for acoustic frequency (octave, 1/3-octave, and narrowband) analysis and sound level measurement. * The construction of a ZigBee network for data communication. In addition, the WeVoice SBIR research team has started working on flight-like devices. Clear directions for improvement were established for the Phase II efforts that may follow. The Phase II program focuses on system integration and optimization, software implementation, and graphical user interface development. An in-situ calibration plan will be suggested and a demonstrable system will be delivered to NASA for testing in a ground facility at the completion of the Phase II contract. So the expected TRL then is expected to reach 6.