January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide1 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Consideration of implantable biomedical systems] Date Submitted: [January, 2007] Source: [Bin Zhen, Huan-Bang Li and Ryuji Kohno] Company [National Institute of Information and Communications Technology (NICT)] Contact: Bin Zhen Voice:[ , Abstract: [This document analyze the performance of IEEE b for implantable systems.] Purpose: [potential technologies for BAN healthcare application.] Notice:This document has been prepared to assist the IEEE P It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein. Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide2 Consideration of implantable biomedical systems B. Zhen, H.-B Li and R. Kohno National Institute of Information and Communications Technology (NICT)

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide3 Motivations Where to start BAN standardization? –from implantable application point of view Review of implanted device research Performance analysis of IEEE b for implantable communication

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide4 High rate implantable applications ApplicationsRequirementsDetail Wireless capsule endoscope (gastrointestinal …) <2Mbps (uplink)2.4GHz, ASK, compressed image (2.18 bit/pixel), sleep/active mode, remote control, <200kbps Analog TV 315MHz, External 433MHz (Korea) Cortical stimulator (auditory, visual, Parkinson’s, …) <3Mbps (downlink), inductive energy couple 32 sites, FSK (0/5MHz, 1/10MHz), 2.5Mbps, >1mW power, 250uA stimulation current (U. of Michigan)

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide5 Low rate implantable applications ApplicationsRequirementsDetail Remote control (pacemaker, actuator …) Inductive link (<1Mbps, asymmetric uplink and downlink) Infrared Carrier frequency (2.5MHz, 4MHz, 10MHz, 13.56MHz …) Modulation (ASK, OOK, FSK, burst sequence, BPSK, LSK) Data rate (125Kbps, 200kbps, 250kbps, 1.12Mbps) Vital signal (pH, pressure, glucose, cardiac arrhythmia …) ISM, MICS and UWB link 15.4b 433MHz (40kbps, ASK, <5m) 403MHz (SubQore, 400kbps, <2m, 0.5% duty cycle) (OOK, 1.2Mbps, 100uw, <0.5m, monopole antenna) Power deliveryInductive coil35Ω coil receiver, 4~13.2mW, 40kHz, 15kHz

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide6 Implantable device Power supply Processor TransceiverInterface BatteryEnergy scavenging External coupling Inductive link ISM, MICS Sensors (image, pressure, glucose, …) Actuators (stimulator, drug pump…) Peripherals (EEG, EMG…) Analog Infrared Power management

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide7 Review summaries Review of >40 published papers –Most of efforts are on implementation –Communication is not optimized Suitable frequency band –Inductive link: <20MHz –MICS, ISM and UWB link: < 5GHz IEEE 2.4GHz and 3~5GHz are OK for low data rate application –The data rate and receiver sensitivity can support through body propagation

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide8 Characteristic of implantable BAN Through body attenuation –Compared with free space pathloss (n=2,3,4), there is an additional 30-35dB attenuation at small distance in the far field –“Towards a propagation model for wireless biomedical applications,” ICC 2003 Energy couple

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide9 New issues of BAN Power issue –Cortical stimulation Data rate issue –250kbps is not high enough Coexistence issue –among wearable device and implanted device Capture effect prefers wearable device to implanted device –among BAN piconets Carrier sense issue –among implanted devices

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide10 Scenarios Piconet APiconet B A1A2 B1B2 A3 IEEE b 2.4GHz ISM band, 1mW transmission power

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide11 Reception power analysis Assumption 20mm tissue media (-40dB tissue attenuation) Maximal distance from implant to an external receiver is <2m

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide12 Carrier sense analysis Free space devices can sense activity of implant when distance is <2m Implant devices can sense activity of another implant when free space distance is <0.2m Assumption 20mm tissue media (-40dB tissue attenuation)

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide13 Coexistence among BAN piconets Assumption two piconets -30dBm adjacent channel limit 1m from implant to external receiver Minimal separation between two piconets in adjacent channels should be >3m Interference from a free space device to implantable device

January, 2007Doc: IEEE ban Zhen, Li, Kohno (NICT) Slide14 Conclusions Summaries of implant device research New issues to consider implantable devices in BAN –Power issue Cortical stimulation –Data rate issue Up to 2Mbps –CCA issue Carrier sense among implants –Coexistence of BAN piconet Interference from free space signal to implantable signal