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開始行:
[[BANSMOM]]
*References [#cfa1a3cd]
-(1)[[心電図を記録するために:2心電図基礎編>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/resident0804-4.pdf]]
-(2)[[QRS_tutorial>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/QRS_tutorial.pdf]]
-(3)[[Performance Analysis of Application-Specific Multicore Systems on Chip>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/PAoASMSoC.pdf]], I. Katib, PhD thesis, 2008.
-(4) [[Pan-Tompkins algorithm to detect QRS complex in ECG signa>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/Pan-Tompkins-algorithm.pdf]]
-(5)[[Pan Algorithm, first Ppaper>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/Pan.pdf]]
-(6) [[A Multiprocessor System-on-Chip for Real-Time Biomedical Monitoring and Analysis: Architectural Design Space Exploration>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/p125-alkhatib.pdf]], DAC 2006.
--[[A Multiprocessor System-on-Chip for Real-Time Biomedical Monitoring and Analysis: Architectural Design Space Exploration>http://www.google.co.jp/url?sa=t&rct=j&q=Design%2Bof%2BSoC%2Bfor%2BECG%2Bsignal%2Bprocessing%2B&source=web&cd=6&ved=0CFkQFjAF&url=http%3A%2F%2Fwww.cs.ucr.edu%2F~harry%2Fclasses_files%2FCS269_07%2Fpapers%2FDAC06_9_1.pdf&ei=laKfTr2hOYPNrQfr5MHgAg&usg=AFQjCNFlLMxniOa5aKmRKuejYhZh6FkJsQ&sig2=Ywl9c4BRZZ06GSB80k8QNA]], DAC 2006, July 24–28, 2006, San Francisco, California, USA.
-(7) [[HARDWARE IMPLEMENTATION OF PAN & TOMPKINS QRS DETECTION ALGORITHM1>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/c8.pdf]], 2003.
-(8)[[A Multiprocessor System-on-Chip for Real-Time Biomedical Monitoring and Analysis: ECG Prototype Architectural Design Space Exploration>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/ACM-TODAES-Iyad.pdf]], 2008
- (9) [[ECG Front-End Design is Simplified with MicroConverter®>http://www.analog.com/library/analogDialogue/archives/37-11/ecg.html]], Analog Devices.
- (10) [[Analog Front-End Design for ECG Systems Using Delta-Sigma ADCs>http://www.ti.com/lit/an/sbaa160a/sbaa160a.pdf]], Application Report,
SBAA160A–March 2009–Revised April 2010
- (11) [[ECG electrode and Skin Interface>http://forum.bgu.co.il/index.php?app=core&module=attach§ion=attach&attach_id=46106]], 2006.
-(12)[[ECG open Project>http://www.open-ecg-project.org/tiki-index.php?page=Hardware]]
-(13) [[How Analog-to-Digital Converter (ADC) Works>http://www.hardwaresecrets.com/article/317]]
-(14) [[Exploring Electrical Engineering>http://www.facstaff.bucknell.edu/mastascu/elessonshtml/StartEE.html]]
-(15) [[Nios II Processor-Based Self-Adaptive QRS Detection System>http://www.altera.com/literature/dc/2007/i2.pdf]], Altera site.
-(16) [[ECG Report Generator (Potable) Graphic Interface>http://cse.spsu.edu/pbobbie/Thesis/Osei's/ECG_Report_Generator__Portable_.ppt]], MS thesis 2006.
-(17) Wireless ECG, [[Volume II>http://innovexpo.itee.uq.edu.au/2002/projects/s358223/thesis.pdf]], [[Volume I>http://innovexpo.itee.uq.edu.au/2002/projects/s354005/thesis.pdf]], BS thesis, Qeenland University, 2002.
-(18) [[Innovations in Health Care Services: The CAALYX System>http://ecaalyx.org/drafts/CAALYX-Innovations.pdf]], Preprint submitted to International Journal of Medical Informatics February 22, 2011.
-(19)[[A 2.6-μW Sub-threshold Mixed-signal ECG SoC>http://www.ee.virginia.edu/rlpvlsi/content/papers/JockeVLSI09.pdf]], S. C. Jocke1, J. F. Bolus, S. N. Wooters1, A. D. Jurik, A. C. Weaver, T. N. Blalock1, and B. H. Calhoun,
*Companies [#ha0b26af]
[[IMEC>http://www2.imec.be/be_en/research/human-biomedical-electronics.html]]
;[[see slides>http://async.org.uk/noc2006/pdf/Eric-Beyne.pdf]]
Imec develops cost-effective and reliable healthcare solutions and tools for the life sciences industry.
Advanced packaging solutions and integration technology developed in the microelectronics industry can enable a strong miniaturization of today’s medical devices. In the future, they can result in completely new devices with additional features and on-board intelligence that can be fabricated cost-effectively.
-[[AfriHealth>http://aitecafrica.com/training]]
-[[Innovation Expo, Qweeland University>http://innovexpo.itee.uq.edu.au/2002/]]
-[[NORDIC>http://nvlsi.no]], Norway
終了行:
[[BANSMOM]]
*References [#cfa1a3cd]
-(1)[[心電図を記録するために:2心電図基礎編>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/resident0804-4.pdf]]
-(2)[[QRS_tutorial>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/QRS_tutorial.pdf]]
-(3)[[Performance Analysis of Application-Specific Multicore Systems on Chip>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/PAoASMSoC.pdf]], I. Katib, PhD thesis, 2008.
-(4) [[Pan-Tompkins algorithm to detect QRS complex in ECG signa>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/Pan-Tompkins-algorithm.pdf]]
-(5)[[Pan Algorithm, first Ppaper>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/Pan.pdf]]
-(6) [[A Multiprocessor System-on-Chip for Real-Time Biomedical Monitoring and Analysis: Architectural Design Space Exploration>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/p125-alkhatib.pdf]], DAC 2006.
--[[A Multiprocessor System-on-Chip for Real-Time Biomedical Monitoring and Analysis: Architectural Design Space Exploration>http://www.google.co.jp/url?sa=t&rct=j&q=Design%2Bof%2BSoC%2Bfor%2BECG%2Bsignal%2Bprocessing%2B&source=web&cd=6&ved=0CFkQFjAF&url=http%3A%2F%2Fwww.cs.ucr.edu%2F~harry%2Fclasses_files%2FCS269_07%2Fpapers%2FDAC06_9_1.pdf&ei=laKfTr2hOYPNrQfr5MHgAg&usg=AFQjCNFlLMxniOa5aKmRKuejYhZh6FkJsQ&sig2=Ywl9c4BRZZ06GSB80k8QNA]], DAC 2006, July 24–28, 2006, San Francisco, California, USA.
-(7) [[HARDWARE IMPLEMENTATION OF PAN & TOMPKINS QRS DETECTION ALGORITHM1>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/c8.pdf]], 2003.
-(8)[[A Multiprocessor System-on-Chip for Real-Time Biomedical Monitoring and Analysis: ECG Prototype Architectural Design Space Exploration>http://webfs-int.u-aizu.ac.jp/~benab/research/projects/bansmom/references/ACM-TODAES-Iyad.pdf]], 2008
- (9) [[ECG Front-End Design is Simplified with MicroConverter®>http://www.analog.com/library/analogDialogue/archives/37-11/ecg.html]], Analog Devices.
- (10) [[Analog Front-End Design for ECG Systems Using Delta-Sigma ADCs>http://www.ti.com/lit/an/sbaa160a/sbaa160a.pdf]], Application Report,
SBAA160A–March 2009–Revised April 2010
- (11) [[ECG electrode and Skin Interface>http://forum.bgu.co.il/index.php?app=core&module=attach§ion=attach&attach_id=46106]], 2006.
-(12)[[ECG open Project>http://www.open-ecg-project.org/tiki-index.php?page=Hardware]]
-(13) [[How Analog-to-Digital Converter (ADC) Works>http://www.hardwaresecrets.com/article/317]]
-(14) [[Exploring Electrical Engineering>http://www.facstaff.bucknell.edu/mastascu/elessonshtml/StartEE.html]]
-(15) [[Nios II Processor-Based Self-Adaptive QRS Detection System>http://www.altera.com/literature/dc/2007/i2.pdf]], Altera site.
-(16) [[ECG Report Generator (Potable) Graphic Interface>http://cse.spsu.edu/pbobbie/Thesis/Osei's/ECG_Report_Generator__Portable_.ppt]], MS thesis 2006.
-(17) Wireless ECG, [[Volume II>http://innovexpo.itee.uq.edu.au/2002/projects/s358223/thesis.pdf]], [[Volume I>http://innovexpo.itee.uq.edu.au/2002/projects/s354005/thesis.pdf]], BS thesis, Qeenland University, 2002.
-(18) [[Innovations in Health Care Services: The CAALYX System>http://ecaalyx.org/drafts/CAALYX-Innovations.pdf]], Preprint submitted to International Journal of Medical Informatics February 22, 2011.
-(19)[[A 2.6-μW Sub-threshold Mixed-signal ECG SoC>http://www.ee.virginia.edu/rlpvlsi/content/papers/JockeVLSI09.pdf]], S. C. Jocke1, J. F. Bolus, S. N. Wooters1, A. D. Jurik, A. C. Weaver, T. N. Blalock1, and B. H. Calhoun,
*Companies [#ha0b26af]
[[IMEC>http://www2.imec.be/be_en/research/human-biomedical-electronics.html]]
;[[see slides>http://async.org.uk/noc2006/pdf/Eric-Beyne.pdf]]
Imec develops cost-effective and reliable healthcare solutions and tools for the life sciences industry.
Advanced packaging solutions and integration technology developed in the microelectronics industry can enable a strong miniaturization of today’s medical devices. In the future, they can result in completely new devices with additional features and on-board intelligence that can be fabricated cost-effectively.
-[[AfriHealth>http://aitecafrica.com/training]]
-[[Innovation Expo, Qweeland University>http://innovexpo.itee.uq.edu.au/2002/]]
-[[NORDIC>http://nvlsi.no]], Norway
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