Digital signal processing in bio-implantable systems

Design challenges and emerging solutions

Seetharam Narasimhan, Jongsun Park, Swarup Bhunia

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

Implantable systems that monitor biological signals require increasingly complex digital signal processing (DSP) electronics for real-time in-situ analysis and compression of the recorded signals. While it is well-known that such signal processing hardware needs to be implemented under tight area and power constraints for small footprint and increased battery-life, new design requirements emerge with their increasing complexity. Use of nanoscale technology shows tremendous benefits in implementing these advanced circuits due to dramatic improvement in integration density and power dissipation per operation. However, it also brings in new challenges such as reliability and high leakage power. Besides, programmability of the device and security of the recorded information are desirable features, which need to be considered during the design of such systems. Programmability is important to adapt to individual subjects as well as to the temporal fluctuations in subject condition. On the other hand, information security is rapidly becoming an important design parameter since the recorded signal often needs to be transmitted outside the body through wireless channels. In this paper, we analyze the emerging issues associated with the design of the DSP unit in an implantable system. We note that conventional design solutions may not be attractive for such systems. However, novel algorithm-architecture-circuit co-design solutions, which leverage on the nature of the signal processing algorithms can be effective to realize ultra low-power, robust, programmable and secure hardware for on-chip realtime signal processing in implantable systems.

Original languageEnglish
Title of host publicationProceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010
Pages223-229
Number of pages7
DOIs
Publication statusPublished - 2010 Sep 17
Event2nd Asia Symposium on Quality Electronic Design, ASQED 2010 - Penang, Malaysia
Duration: 2010 Aug 32010 Aug 4

Other

Other2nd Asia Symposium on Quality Electronic Design, ASQED 2010
CountryMalaysia
CityPenang
Period10/8/310/8/4

Fingerprint

Digital signal processing
Systems analysis
Signal processing
Hardware
Networks (circuits)
Security of data
Energy dissipation
Electronic equipment

Keywords

  • Bio-implantable systems
  • Digital signal processing
  • Neural interface
  • Ultralow power design

ASJC Scopus subject areas

  • Electrical and Electronic Engineering
  • Safety, Risk, Reliability and Quality

Cite this

Narasimhan, S., Park, J., & Bhunia, S. (2010). Digital signal processing in bio-implantable systems: Design challenges and emerging solutions. In Proceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010 (pp. 223-229). [5548247] https://doi.org/10.1109/ASQED.2010.5548247

Digital signal processing in bio-implantable systems : Design challenges and emerging solutions. / Narasimhan, Seetharam; Park, Jongsun; Bhunia, Swarup.

Proceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010. 2010. p. 223-229 5548247.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Narasimhan, S, Park, J & Bhunia, S 2010, Digital signal processing in bio-implantable systems: Design challenges and emerging solutions. in Proceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010., 5548247, pp. 223-229, 2nd Asia Symposium on Quality Electronic Design, ASQED 2010, Penang, Malaysia, 10/8/3. https://doi.org/10.1109/ASQED.2010.5548247
Narasimhan S, Park J, Bhunia S. Digital signal processing in bio-implantable systems: Design challenges and emerging solutions. In Proceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010. 2010. p. 223-229. 5548247 https://doi.org/10.1109/ASQED.2010.5548247
Narasimhan, Seetharam ; Park, Jongsun ; Bhunia, Swarup. / Digital signal processing in bio-implantable systems : Design challenges and emerging solutions. Proceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010. 2010. pp. 223-229
@inproceedings{4da50a25ba944e0aa2198d058ab1971d,
title = "Digital signal processing in bio-implantable systems: Design challenges and emerging solutions",
abstract = "Implantable systems that monitor biological signals require increasingly complex digital signal processing (DSP) electronics for real-time in-situ analysis and compression of the recorded signals. While it is well-known that such signal processing hardware needs to be implemented under tight area and power constraints for small footprint and increased battery-life, new design requirements emerge with their increasing complexity. Use of nanoscale technology shows tremendous benefits in implementing these advanced circuits due to dramatic improvement in integration density and power dissipation per operation. However, it also brings in new challenges such as reliability and high leakage power. Besides, programmability of the device and security of the recorded information are desirable features, which need to be considered during the design of such systems. Programmability is important to adapt to individual subjects as well as to the temporal fluctuations in subject condition. On the other hand, information security is rapidly becoming an important design parameter since the recorded signal often needs to be transmitted outside the body through wireless channels. In this paper, we analyze the emerging issues associated with the design of the DSP unit in an implantable system. We note that conventional design solutions may not be attractive for such systems. However, novel algorithm-architecture-circuit co-design solutions, which leverage on the nature of the signal processing algorithms can be effective to realize ultra low-power, robust, programmable and secure hardware for on-chip realtime signal processing in implantable systems.",
keywords = "Bio-implantable systems, Digital signal processing, Neural interface, Ultralow power design",
author = "Seetharam Narasimhan and Jongsun Park and Swarup Bhunia",
year = "2010",
month = "9",
day = "17",
doi = "10.1109/ASQED.2010.5548247",
language = "English",
isbn = "9781424478088",
pages = "223--229",
booktitle = "Proceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010",

}

TY - GEN

T1 - Digital signal processing in bio-implantable systems

T2 - Design challenges and emerging solutions

AU - Narasimhan, Seetharam

AU - Park, Jongsun

AU - Bhunia, Swarup

PY - 2010/9/17

Y1 - 2010/9/17

N2 - Implantable systems that monitor biological signals require increasingly complex digital signal processing (DSP) electronics for real-time in-situ analysis and compression of the recorded signals. While it is well-known that such signal processing hardware needs to be implemented under tight area and power constraints for small footprint and increased battery-life, new design requirements emerge with their increasing complexity. Use of nanoscale technology shows tremendous benefits in implementing these advanced circuits due to dramatic improvement in integration density and power dissipation per operation. However, it also brings in new challenges such as reliability and high leakage power. Besides, programmability of the device and security of the recorded information are desirable features, which need to be considered during the design of such systems. Programmability is important to adapt to individual subjects as well as to the temporal fluctuations in subject condition. On the other hand, information security is rapidly becoming an important design parameter since the recorded signal often needs to be transmitted outside the body through wireless channels. In this paper, we analyze the emerging issues associated with the design of the DSP unit in an implantable system. We note that conventional design solutions may not be attractive for such systems. However, novel algorithm-architecture-circuit co-design solutions, which leverage on the nature of the signal processing algorithms can be effective to realize ultra low-power, robust, programmable and secure hardware for on-chip realtime signal processing in implantable systems.

AB - Implantable systems that monitor biological signals require increasingly complex digital signal processing (DSP) electronics for real-time in-situ analysis and compression of the recorded signals. While it is well-known that such signal processing hardware needs to be implemented under tight area and power constraints for small footprint and increased battery-life, new design requirements emerge with their increasing complexity. Use of nanoscale technology shows tremendous benefits in implementing these advanced circuits due to dramatic improvement in integration density and power dissipation per operation. However, it also brings in new challenges such as reliability and high leakage power. Besides, programmability of the device and security of the recorded information are desirable features, which need to be considered during the design of such systems. Programmability is important to adapt to individual subjects as well as to the temporal fluctuations in subject condition. On the other hand, information security is rapidly becoming an important design parameter since the recorded signal often needs to be transmitted outside the body through wireless channels. In this paper, we analyze the emerging issues associated with the design of the DSP unit in an implantable system. We note that conventional design solutions may not be attractive for such systems. However, novel algorithm-architecture-circuit co-design solutions, which leverage on the nature of the signal processing algorithms can be effective to realize ultra low-power, robust, programmable and secure hardware for on-chip realtime signal processing in implantable systems.

KW - Bio-implantable systems

KW - Digital signal processing

KW - Neural interface

KW - Ultralow power design

UR - http://www.scopus.com/inward/record.url?scp=77956501574&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=77956501574&partnerID=8YFLogxK

U2 - 10.1109/ASQED.2010.5548247

DO - 10.1109/ASQED.2010.5548247

M3 - Conference contribution

SN - 9781424478088

SP - 223

EP - 229

BT - Proceedings of the 2nd Asia Symposium on Quality Electronic Design, ASQED 2010

ER -