Table of Contents

• Body area wireless sensor networks for the analysis of cycling performanceRaluca Marin-Perianu, Mihai Marin-Perianu, David Rouffet, Simon Taylor, Paul J. M. Havinga, Rezaul K. Begg, Marimuthu Palaniswami. 1-7 [doi]
• Secure handshake with symptoms-matching: the essential to the success of mhealthcare social networkRongxing Lu, Xiaodong Lin, Xiaohui Liang, Xuemin (Sherman) Shen. 8-15 [doi]
• Practical comparison of ranging in IEEE 802.15.4 and IEEE 802.15.4a medical body sensor networksDries Neirynck, Kathleen Philips, Harmke de Groot, Javier Espina. 16-22 [doi]
• Context-aware body area networks (CABAN) for interactive smart environments: interference characterizationSean F. Heaney, Emi Garcia-Palacios, William G. Scanlon. 23-28 [doi]
• Demonstration of a novel wireless three-pad ECG system for generating conventional 12-lead signalsHuasong Cao, Haoming Li, Leo J. Stocco, Victor C. M. Leung. 29-32 [doi]
• DynAGreen: hierarchical dynamic energy efficient task assignment for wireless healthcare systemsPriti Aghera, Dilip Krishnaswamy, Tajana Rosing. 33-36 [doi]
• Body area network for first responders: a case studyKrzysztof Piotrowski, Anna Sojka, Peter Langendörfer. 37-40 [doi]
• Node mobility support in body sensor networksBart Braem, Peter De Cleyn, Chris Blondia. 41-44 [doi]
• Evaluating relaying scheme for BAN TDMA MAC using a space-time dependent channel modelMickael Maman, Laurent Ouvry. 45-51 [doi]
• A single conductive surface as communication media for networked devicesJosep Rius. 52-58 [doi]
• Low power high bandwidth power-line communication network for wearable applicationsMichel Chedid, Ilja Belov, Peter Leisner. 59-64 [doi]
• Mobile device aided cooperative transmission for body area networksRong Yu, Yan Zhang, Ruchao Gao. 65-70 [doi]
• Low power u-healthcare services using MDC packet-level scheduling for in/on-body wireless multi-hop links in a medical body area networkKi-Dong Lee, Sang G. Kim, Byung K. Yi. 71-76 [doi]
• A robust protocol stack for multi-hop wireless body area networks with transmit power adaptationMajid Nabi, Twan Basten, Marc Geilen, Milos Blagojevic, Teun Hendriks. 77-83 [doi]
• Design and evaluation of a novel wireless three-pad ECG system for generating conventional 12-lead signalsHuasong Cao, Haoming Li, Leo J. Stocco, Victor C. M. Leung. 84-90 [doi]
• Adaptive and personalized body networkingNikola B. Serbedzija, Gian Mario Bertolotti. 91-97 [doi]
• Contention vs. polling: a study in body area networks MAC designAthanassios Boulis, Yuriy Tselishchev. 98-104 [doi]
• Performance analysis of a BPSK-BPPM UWB physical layer for wireless body area networksStephane Mebaley Ekome, Jean Schwoerer, Geneviève Baudoin, Martine Villegas. 105-111 [doi]
• An ultra wideband propagation model for wireless cardiac monitoring devicesRaúl Chávez-Santiago, Ali Khaleghi, Ilangko Balasingham. 112-116 [doi]
• Microsensors for continuous monitoring of heart functionLars Hoff, Kristin Imenes, Lars A. Fleischer, Per Steinar Halvorsen, Andreas Espinoza, Espen W. Remme, Ole Jakob Elle, Erik Fosse. 117-123 [doi]
• Candidate estimators for aorta diameter estimation using monostatic radarLars Erik Solberg, Ilangko Balasingham, Svein-Erik Hamran. 124-130 [doi]
• From posture to motion: the challenge for real time wireless inertial motion captureAlexander D. Young. 131-137 [doi]
• Characterizing and minimizing synchronization and calibration errors in inertial body sensor networksShanshan Chen, Jeff S. Brantley, Taeyoung Kim, John Lach. 138-144 [doi]
• WBAN system using GPPM algorithm for IEEE 802.15.TG6Jae Ho Hwang, Jae-Moung Kim. 145-149 [doi]
• Behavioral reconfigurable compression in body sensor networksFoad Dabiri, Hyduke Noshadi, Majid Sarrafzadeh. 150-156 [doi]
• A mobile core-body temperature monitoring system on AndroidOrlando R. E. Pereira, João M. L. P. Caldeira, Lei Shu, Joel J. P. C. Rodrigues. 157-163 [doi]
• Unsupervised learning in body-area networksNicola Bicocchi, Matteo Lasagni, Marco Mamei, Andrea Prati, Rita Cucchiara, Franco Zambonelli. 164-170 [doi]
• A novel approach to multi-sensor data synchronization using mobile phonesJonas Wåhslén, Thomas Lindh, Martin Eriksson. 171-174 [doi]
• A biomedical wireless sensor network for hemodynamic monitoringKarl Øyri, Stig Støa, Erik Fosse. 175-180 [doi]
• Body area networks for ambulatory psychophysiological monitoring: a survey of off-the-shelf sensor systemsKatarzyna Wac, Anind K. Dey, Athanasios V. Vasilakos. 181-187 [doi]
• Monitoring body temperature of newborn infants at neonatal intensive care units using wearable sensorsWei Chen 0015, Sietse Dols, Sidarto Bambang-Oetomo, Loe M. G. Feijs. 188-194 [doi]
• Towards implementing a fully wireless multiple-lead electrocardiographGill R. Tsouri. 195-200 [doi]
• Grouped variable model selection for heterogeneous medical signalsJamie Macbeth, Majid Sarrafzadeh. 201-207 [doi]
• Wireless body sensor design for intra-vaginal temperature monitoringJoão F. R. Garcia, João M. L. P. Caldeira, Joel J. P. C. Rodrigues. 208-213 [doi]
• A wearable motion trackerFahad Moiz, W. Daniel Leon-Salas, Yugyung Lee. 214-219 [doi]
• A wearable platform utilizing off-the-shelf components and performing quality analysis of physiological dataAlexandros Pantelopoulos, Nikolaos G. Bourbakis. 220-226 [doi]
• Battery-aware power management techniques for wearable haptic nodesMahsan Rofouei, Elisabetta Farella, Davide Brunelli, Majid Sarrafzadeh, Luca Benini. 227-232 [doi]
• PAMS: a wearable physical activity monitoring system for continuous motion capture in free-living environmentsSheng Hu, Xi Chen, Jindong Tan. 233-239 [doi]
• DarSens: a framework for distributed activity recognition from body-worn sensorsMichael Haslgrübler, Clemens Holzmann. 240-246 [doi]