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Biomed Eng Lett (2013) 3:32-38 DOI 10.1007/s13534-013-0085-z ORIGINAL ARTICLE A Study of Reliable Bio-Telemetry, Efficient Powering and Electromagnetic Exposure in Implantable Neural Systems Ahmed I. AL-Kalbani, Mehmet R. Yuce and Jean-Michel Redouté Received: 15 January 2013 / Revised: 17 March 2013 / Accepted: 19 March 2013 © The Korean Society of Medical & Biological Engineering and Springer 2013 Abstract INTRODUCTION Purpose This paper explores the bio-telemetry, powering and electromagnetic exposure design concerns in implanted Injured auditory or visual nerve cells lead to respective neural systems. impairments in a subject’s hearing or vision. Neural implanted Methods A class-E transmitter transfers PWM-ASK (Pulse- interfaces overcome these disabilities by conveying the missing Width Modulated Amplitude-Shift Keying) modulated data sensory information to the brain [1, 2]. Biomedical implants signals to the brain implants at an optimal speed, while require a modulation scheme that provides a continuous efficiently delivering sufficient power so as to keep the power level even when no data is being transmitted [3]. A exposure of tissue to electromagnetic fields within tolerable Pulse-Width Modulated Amplitude-Shift Keying (PWM- limits. ASK) meets the entire above criterion and is found to be a Results A case study design illustrates that using a PWM- suitable
Biomedical Engineering Letters – Springer Journals
Published: Apr 14, 2013
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