SBIR-STTR Award

Sensor Image-Based Environmental Listening Assistant
Award last edited on: 4/11/2016

Sponsored Program
SBIR
Awarding Agency
NIH : NIDCD
Total Award Amount
$218,912
Award Phase
1
Solicitation Topic Code
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Principal Investigator
Richard S Goldhor

Company Information

Speech Technology & Applied Research Corp (AKA: STAR Analytical Services)

54 Middlesex Turnpike
Bedford, MA 01730
Location: Single
Congr. District: 06
County: Middlesex

Phase I

Contract Number: ----------
Start Date: ----    Completed: ----
Phase I year
2016
Phase I Amount
$218,912
Environmental Listening Assistance from Sensor Images Recent years have witnessed a veritable explosion of innovative personal audio devices, wireless sound systems, active earpieces, and other personal digital audio devices. These appliances are typically much less expensive, and seemingly much more innovative, than traditional hearing aids. But hearing aids are subject to many constraints that their more innovative and uninhibited cousins ignore. These constraints include significant size and power limitations, and stringent signal processing latency. These greatly limit the potential of many innovations, even though they could be relaxed if an aid could be environmentally connected and aware. From a recent NIDCD workshop report: "The result [of these constraints] is a wide `valley of death' that limits the ability to translate innovations from academic research into widespread commercial use." We propose a system for environmental awareness based on separated sensor images: the signals that microphones would produce from single sources, if all others were quiet. Critically, these allow determining whether a latency constraint even matters for a given source of interest. Modular system design will allow it to make use of further innovations in both consumer audio and academic research as they arise. The many different audio processing capabilities of present-day hearing aids fall into two categories: user- centered compensations for hearing deficits (e.g. amplification, dynamic range compression, frequency transposition), and for the undesirable side-effects of hearing aid operation (e.g. feedback suppression); and acoustic space-centered signal enhancement techniques designed to compensate for the complexities of a user's acoustic environment (e.g. speaker separation, noise reduction, speech enhancement, echo cancella- tion). Broadly speaking, present day hearing aids do a much better job of compensating for user-centered characteristics than space-centered characteristics. It is precisely this weakness that this project addresses. We propose to develop an assistive listening product designed to be located in an acoustic space, rather than worn by a listener. This Environmental Listening Assistant or ELA would be part of the every-day envi- ronmental support that hearing aid users could expect to find in their home, car, or office-just as they expect to find appropriate lighting that allows them to see well. The ELA would communicate bidirectionally with any ELA-aware hearing aid, and could support multiple hearing aid users simultaneously. Just as a room's lighting infrastructure typically includes multiple light emitting devices and a switch, a room's ELA infrastructure would include multiple microphones and a control box. The ELA control box would continually process microphone signals to create separate output audio channels, one for each active audio source. When a listener wearing an ELA-aware hearing aid entered the room, they would use a simple interface running on their smartphone, smartwatch, or similar device to choose one of the ELA source images to listen to. The ELA will help hearing aid users to better hear the sounds they want to hear in complex acoustic spaces.

Public Health Relevance Statement:


Public Health Relevance:
Environmental Listening Assistance Present-day hearing aids try to do many different things, but generally do a better job with user-centered compensations (e.g., signal amplification, dynamic range compression, and feedback suppression) than with acoustic space-centered signal enhancement tasks such as speaker separation, noise reduction, speech enhancement, and echo cancellation. These latter tasks are hard for a tiny device placed in or by a user's ear to do well, and could be carried out much more successfully by a separate device temporarily or permanently located in a room, car, or other acoustic space. We propose to improve hearing healthcare by developing an Environmental Listening Assistant, which would be placed in a room to separate out individual sounds and, consistent with the constraints of hearing aids, deliver the best rendition of them to the aids of listeners in the vicinity upon request.

Project Terms:
Accounting; Acoustics; Address; Adult; Adverse effects; Algorithms; Attention; Awareness; base; Binding (Molecular Function); blind; Boxing; Categories; Cellular Phone; Cessation of life; Characteristics; Complex; Complex Mixtures; cost; Data; design; Development; Devices; digital; Ear structure; Educational workshop; Effectiveness; Electronics; Environment; Explosion; falls; Feedback; Financial compensation; Frequencies (time pattern); Healthcare; Hearing; Hearing Aids; hearing impairment; Heart; Home environment; Image; improved; Individual; innovation; Intellectual Property; interest; Light; Lighting; Measures; mHealth; millisecond; Music; National Institute on Deafness and Other Communication Disorders; next generation; Noise; novel; Occupations; operation; Output; Participant; Play; Process; public health relevance; Reporting; Research; Research Infrastructure; Residual state; response; Running; sensor; signal processing; Signal Transduction; sound; Source; Specific qualifier value; Speech; Speech Intelligibility; Stream; success; System; Techniques; Technology; tool; Translating; Wireless Technology; World Health Organization

Phase II

Contract Number: ----------
Start Date: ----    Completed: ----
Phase II year
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Phase II Amount
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