balance-fp7.eu
BALANCE | Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons.
http://www.balance-fp7.eu/links.php
Balance Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons. This project has received funding from the European Union’s Seventh Programme for research, technological development and demonstration under grant agreement No. 601003, for the period 2013-01-01 to 2017-02-28. The biggest challenge in exoskeletons. What is the biggest challenge in exoskeleton technology, according to Karl Gudmundsson - Vice President of Marketing, Ekso Bionics? Dr Je Hyung Jung.
amam2015.mit.edu
Scientific Committee | amam2015
http://amam2015.mit.edu/committees/scientific-committee
Skip to main content. June 21 - 25, 2015 Cambridge, MA USA. AMAM 2013, Gemany. AMAM 2011, Japan. AMAM 2008, USA. AMAM 2005, Germany. AMAM 2003, Japan. AMAM 2000, Canada. The scientific committee is composed of:. September 28, 2016. AMAM 2013, Gemany. AMAM 2011, Japan. AMAM 2008, USA. AMAM 2005, Germany. AMAM 2003, Japan. AMAM 2000, Canada. Swimming lizards, sidewinding snakes, and digging ants: animal and robophysical experiments reveal principles of effective environmental interaction.
balance-fp7.eu
BALANCE | Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons.
http://www.balance-fp7.eu/objectives.php
Balance Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons. This project has received funding from the European Union’s Seventh Programme for research, technological development and demonstration under grant agreement No. 601003, for the period 2013-01-01 to 2017-02-28. In order to move exoskeletons-for-walking toward real life applications, BALANCE will realize a platform-independent control strategy. On robust balance performance. That are very common for ...
balance-fp7.eu
BALANCE | Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons.
http://www.balance-fp7.eu/consortium.php
Balance Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons. This project has received funding from the European Union’s Seventh Programme for research, technological development and demonstration under grant agreement No. 601003, for the period 2013-01-01 to 2017-02-28. The project consortium is made up of 8 partners:. Tecnalia Research and Innovation. Responsible person / PI:. Dr Je Hyung Jung. Haritz Zabaleta M.Sc. Julius Klein, PhD. Joseph McIntyre, PhD.
balance-fp7.eu
BALANCE | Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons.
http://www.balance-fp7.eu/docs.php
Balance Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons. This project has received funding from the European Union’s Seventh Programme for research, technological development and demonstration under grant agreement No. 601003, for the period 2013-01-01 to 2017-02-28. Report on "Proactive and reactive kinematics during various walking manoeuvres", deliverable 7.2 of the project. July 22, 2016 Published by Administrator. Consortium Publication Overview 2015.
balance-fp7.eu
BALANCE | Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons.
http://www.balance-fp7.eu/news.php
Balance Augmentation in Locomotion, through Anticipative, Natural and Cooperative control of Exoskeletons. This project has received funding from the European Union’s Seventh Programme for research, technological development and demonstration under grant agreement No. 601003, for the period 2013-01-01 to 2017-02-28. BALANCE launches Frontiers Research Topic "On the Forefront of Control for Wearable Robots". July 28, 2016 Published by Administrator. BALANCE important contributor to WearRAcon. This newslet...
biobiped.de
BioBiped Project: Home
http://www.biobiped.de/index/video
The vision of humanoid robots which mimic abilities of humans has inspired researchers for decades. Yet transferring human abilities into a robotic counterpart has proven to be highly challenging in most cases. The recently launched BioBiped project aims at realizing human-like three-dimensional running, walking and standing and herewith allowing the free selection of speed and gait. For achieving this goal, the SIM Group of TU Darmstadt. And the Locomotion Laboratory of TU Darmstadt. In 2010, BioBiped1.