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George Andrikopoulos
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2020 – today
- 2024
- [c33]Caroline Yan Zheng, Georgios Andrikopoulos, Mark Paterson, Nadia Berthouze, Minna Orvokki Nygren, Yoav Luft, Madeline Balaam:
Towards Robot and Technologies that Touch Well - Shaping an Experience-driven Design Paradigm. Conference on Designing Interactive Systems (Companion Volume) 2024 - [c32]Algot Lindestam, Seshagopalan Thorapalli Muralidharan, Georgios Andrikopoulos, Randy Gomez:
Model Identification of a Soft Robotic Eye Actuator for Safe Social Interactions. AIM 2024: 211-216 - [c31]Georgios Andrikopoulos, Lars Hässler, Randy Gomez:
On the Design of a Soft Robotic Neck for the Social Robot HARU. AIM 2024: 428-433 - 2023
- [c30]Seshagopalan Thorapalli Muralidharan, Georgios Andrikopoulos, Lei Feng:
A Survey on the Current Trends and Applications of Design Optimization for Compliant and Soft Robotics. AIM 2023: 47-53 - [c29]Christos Andreanidis, Johanna Bergsten, Marcel Brümmer, Joel Fröberg, Algot Lindestam, Annie Persson, Fahim Pirmohamed, Maria Sandahl, Seshagopalan Thorapalli Muralidharan, Georgios Andrikopoulos:
On the Design and Development of a Tabletop Robot for Interaction with Children. AIM 2023: 1232-1237 - 2022
- [j5]Qinglei Ji, Shuo Fu, Kaige Tan, Seshagopalan Thorapalli Muralidharan, Karin Lagrelius, David Danelia, Georgios Andrikopoulos, Xi Vincent Wang, Lihui Wang, Lei Feng:
Synthesizing the optimal gait of a quadruped robot with soft actuators using deep reinforcement learning. Robotics Comput. Integr. Manuf. 78: 102382 (2022) - [c28]Qinglei Ji, Shuo Fu, Lei Feng, George Andrikopoulos, Xi Vincent Wang, Lihui Wang:
Omnidirectional walking of a quadruped robot enabled by compressible tendon-driven soft actuators. IROS 2022: 11015-11022 - [c27]Vasiliki Theofili Nikolaidi, George Andrikopoulos, Dimitris Tsipianitis, Dimosthenis Kazakos:
EMG Onset and Offset Detection via a Modified Threshold Crossings Algorithm. MED 2022: 1111-1116 - 2021
- [j4]Andreas Papadimitriou, George Andrikopoulos, George Nikolakopoulos:
On the Optimal Adhesion Control of a Vortex Climbing Robot. J. Intell. Robotic Syst. 102(3): 57 (2021) - 2020
- [c26]Andreas Papadimitriou, George Andrikopoulos, George Nikolakopoulos:
Experimental Evaluation of an Explicit Model Predictive Controller for an Adhesion Vortex Actuated Climbing Robot. ACC 2020: 2137-2142 - [c25]Vasileios Skaramagkas, George Andrikopoulos, Stamatis Manesis:
An Experimental Investigation of Essential Hand Tremor Suppression via a Soft Exoskeletal Glove. ECC 2020: 889-894 - [c24]Andreas Papadimitriou, George Andrikopoulos, George Nikolakopoulos:
On Path Following Evaluation for a Tethered Climbing Robot. IECON 2020: 656-661 - [c23]Vasileios Skaramagkas, George Andrikopoulos, Zinovia Kefalopoulou, Panagiotis Polychronopoulos:
Towards Differential Diagnosis of Essential and Parkinson's Tremor via Machine Learning. MED 2020: 782-787
2010 – 2019
- 2019
- [j3]George Andrikopoulos, George Nikolakopoulos:
Vortex Actuation via Electric Ducted Fans: an Experimental Study. J. Intell. Robotic Syst. 95(3-4): 955-973 (2019) - [c22]Andreas Papadimitriou, George Andrikopoulos, George Nikolakopoulos:
Development and Control of a Differential Wall Climbing Robot based on Vortex Adhesion. ECC 2019: 1610-1615 - [c21]Angelica Brusell, Georgios Andrikopoulos, George Nikolakopoulos:
Vortex Robot Platform for Autonomous Inspection: Modeling and Simulation. IECON 2019: 756-762 - [c20]Andreas Papadimitriou, Georgios Andrikopoulos, Angelica Brusell, George Nikolakopoulos:
On Adhesion Modeling and Control of a Vortex Actuator for Climbing Robots. INDIN 2019: 571-576 - [c19]George Andrikopoulos, Andreas Papadimitriou, Angelica Brusell, George Nikolakopoulos:
On Model-based Adhesion Control of a Vortex Climbing Robot. IROS 2019: 1460-1465 - 2018
- [c18]Georgios Andrikopoulos, George Nikolakopoulos:
Design, Development and Experimental Evaluation of a Vortex Actuation System. MESA 2018: 1-6 - [c17]Andreas Papadimitriou, George Andrikopoulos, George Nikolakopoulos:
Design, Development and Experimental Evaluation of a Thrust Vectoring Vortex Climbing Robot. ROBIO 2018: 1341-1346 - [c16]Georgios A. Zachiotis, George Andrikopoulos, Randy Gornez, Keisuke Nakamura, George Nikolakopoulos:
A Survey on the Application Trends of Home Service Robotics. ROBIO 2018: 1999-2006 - [c15]Mohammed Elbadawi, George Andrikopoulos, George Nikolakopoulos, Thomas Gustafsson:
Bio-Inspired Climbing Robots in Wet Environments: Recent Trends in Adhesion Methods and Materials. ROBIO 2018: 2347-2353 - 2017
- [c14]George Andrikopoulos, George Nikolakopoulos:
Design, development and control of a human-inspired two-arm robot via Pneumatic Artificial Muscles. MED 2017: 241-246 - [c13]Angelica Brusell, George Andrikopoulos, George Nikolakopoulos:
Novel considerations on the negative pressure adhesion of electric ducted fans: An experimental study. MED 2017: 1404-1409 - 2016
- [c12]Ulrik Mamikoglu, George Andrikopoulos, George Nikolakopoulos, Ulrik Röijezon, Mascha Pauelsen, Thomas Gustafsson:
Electromyography based joint angle estimation and control of a robotic leg. BioRob 2016: 182-187 - [c11]George Andrikopoulos, George Nikolakopoulos, Dariusz Kominiak, Åsa Unander-Scharin:
Towards the development of a novel upper-body pneumatic humanoid: Design and implementation. ECC 2016: 395-400 - [c10]Angelica Brusell, George Andrikopoulos, George Nikolakopoulos:
A survey on pneumatic wall-climbing robots for inspection. MED 2016: 220-225 - [c9]David Wuthier, Dariusz Kominiak, Christoforos Kanellakis, Georgios Andrikopoulos, Matteo Fumagalli, G. Schipper, George Nikolakopoulos:
On the design, modeling and control of a novel compact aerial manipulator. MED 2016: 665-670 - [c8]O. C. Carholt, Emil Fresk, George Andrikopoulos, George Nikolakopoulos:
Design, modelling and control of a Single Rotor UAV. MED 2016: 840-845 - [c7]Elias Small, Emil Fresk, George Andrikopoulos, George Nikolakopoulos:
Modelling and control of a Tilt-Wing Unmanned Aerial Vehicle. MED 2016: 1254-1259 - [c6]George Andrikopoulos, George Nikolakopoulos:
On the design, development and motion control of a HUmanoid Robotic Leg via pneumatic artificial muscles. ROBIO 2016: 1637-1642 - 2015
- [c5]George Andrikopoulos, George Nikolakopoulos, Stamatis Manesis:
Motion control of a novel robotic wrist exoskeleton via pneumatic muscle actuators. ETFA 2015: 1-8 - [c4]George Andrikopoulos, George Nikolakopoulos, Stamatis Manesis:
Incorporation of thermal expansion in static force modeling of Pneumatic Artificial Muscles. MED 2015: 414-420 - 2014
- [j2]George Andrikopoulos, George Nikolakopoulos, Ioannis Arvanitakis, Stamatis Manesis:
Piecewise Affine Modeling and Constrained Optimal Control for a Pneumatic Artificial Muscle. IEEE Trans. Ind. Electron. 61(2): 904-916 (2014) - [j1]George Andrikopoulos, George Nikolakopoulos, Stamatis Manesis:
Advanced Nonlinear PID-Based Antagonistic Control for Pneumatic Muscle Actuators. IEEE Trans. Ind. Electron. 61(12): 6926-6937 (2014) - [c3]Dimitris Gryparis, George Andrikopoulos, Stamatis Manesis:
Parallel Robotic Manipulation via Pneumatic Artificial Muscles. ICINCO (2) 2014: 29-36 - 2013
- [c2]George Andrikopoulos, George Nikolakopoulos, Stamatis Manesis:
Adaptive Internal Model Control scheme for a Pneumatic Artificial Muscle. ECC 2013: 772-777 - [c1]George Andrikopoulos, George Nikolakopoulos, Stamatis Manesis:
Non-linear control of Pneumatic Artificial Muscles. MED 2013: 729-734
Coauthor Index
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last updated on 2024-11-04 21:39 CET by the dblp team
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