Hardware-efficient auto-reconfigurable hearing aids using 3-level octave interpolated filters for auditory compensation applications

• Main Authors: Devis, T. (Author), Manuel, M. (Author)
• Format: Article
• Language: English
• Published: Springer Science and Business Media Deutschland GmbH 2021
• Subjects: Article; Audiogram; audiography; Audition; Auto-reconfigurable; Coefficient multiplier; computer; Computer hardware; Computers; Cost effectiveness; Cost-effective implementations; Filter bank; Fractional interpolation; Hardware implementations; hearing aid; Hearing aid; Hearing aids; Hearing Aids; Hearing disabilities; hearing impairment; Hearing Loss; human; Humans; Interpolated filters; Matching error; mathematical model; Multirate system; Reconfigurable filters; Reconfigurable hardware; Reconfigurable structure
• Online Access: View Fulltext in Publisher

 A reconfigurable hearing aid is a generic type that can be used for various hearing disabilities without modifying the device hardware. This requires several trials to identify the best matching with the impaired person’s audiogram. The objective of this paper is to propose a novel reconfigurable hearing aid of low complexity with auto-adapting capability which makes it suitable for different types of hearing disabilities ranging from mild to severe intensities. The audio spectrum is divided into three regions and for each region, four different schemes are proposed. An automatic selection of the optimum scheme is proposed for all the regions based on hearing thresholds. Octave and fractional interpolation techniques are performed on a Parks-McClellan based prototype filter to generate the various sub-bands in the reconfigurable filter bank structure. The proposed structure uses only 18 coefficient multipliers which save up to 92% of multipliers when compared to other designs. The delay and matching errors are within the globally accepted limits. The hardware implementation executed on Xilinx Kintex-7 FPGA development board has reaffirmed that the structure is compact and power-efficient. The proposed auto-reconfigurable structure can be used for various types of hearing impairments and can avoid the manual interventions for the selection of schemes in audiogram matching. This in turn minimizes the time to establish the best match with the audiogram. Since the proposed structure has minimal complexity, cost-effective implementation of the device is also possible. © 2021, Australasian College of Physical Scientists and Engineers in Medicine.