Biblio
Local input-output stability of recurrent networks with time-varying weights. Proc. European Symposium Artificial Neural Networks. :281–286.
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2000. What do humanoid robots offer to experimental psychology ? Connectionist models of neurocognition and emergent behavior : from theory to applications ; proceedings of the 12th Neural Computation and Psychology Workshop, Birkbeck, University of London, 8 - 10 April 2010. 20:361–371.
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2011. Mit KI zu mehr Teilhabe in der Arbeitswelt: Potenziale, Einsatzmöglichkeiten und Herausforderungen. Whitepaper aus der Plattform Lernende Systeme.
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2023. Input-Output Stability of Recurrent Neural Networks with Delays using Circle Criteria. Proc. Int. ICSC/IFAC Symposium on Neural Computation. :519–525.
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1998. Online stability of backpropagation-decorrelation recurrent learning. Neurocomputing. 69:642–650.
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2006. Lernen und Sicherheit in Interaktion mit Robotern aus Maschinensicht. Robotik und Gesetzgebung. 2:51–71.
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2013. Situated robot learning for multi-modal instruction and imitation of grasping. Robotics and Autonomous Systems. 47:129–141.
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2004. Robust control in closed loops realised by fast signal transmission of infinite gain neurons. Proc. Int. Conf. Artificial Neural Networks. 1:260–266.
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2000. Humans and Humanoids - Perspectives on Research in Cognition and Robotics. KI - Künstliche Intelligenz. 4:33–36.
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2008. .
1999. Unsupervised Clustering of Continuous Trajectories of Kinematic Trees with SOM-SD. Proc. European Symposium on Artificial Neural Networks.
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2006. "Können Maschinen Ethisches Verhalten Lernen ?" Bericht zum 1. SYnENZ Zirkel der BWG Kommission für Synergie und Intelligenz (SYnENZ) Jahrbuch der Braunschweigischen Wissenschaftlichen Gesellschaft. :117-120.
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2021. Robotic Systems in Operating Theatres: New Forms of Team-Machine Interaction in Health Care - On Challenges for Health Information Systems on Adequately Considering Hybrid Action of Humans and Machines. Methods of Information in Medicine. 58:e14-e25.
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2019. Integrating Feature Maps and Competitive Layer Architectures For Motion Segmentation. Neurocomputing. 74:1372–1381.
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2011. Neural competition for motion segmentation. 18th European Symposium on Artificial Neural Networks, Computational Intelligence and Machine Learning (ESANN). :59–64.
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2010. Object Recognition and Pose Estimation with a Fast and Versatile 3D Robot Sensor. Proceedings of the 11th International Conference on Pattern Recognition. :684–687.
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1992. Objekterkennung und Lagebestimmung mit einem 3D-Robotsensor. Informationstechnik und Technische Informatik (it+ti). 1/94:39–46.
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1994. Automatisierung mit Industrierobotern. :257-270.
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1988. Fast and Versatile Range Data Acquisition in a Robot Work Cell. IEEE International Conference on Intelligent Robots and Systems. :1169–1174.
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1992. Polyhedral Object Recognition by Hough Space Analysis. Geobild. 51:165-172.
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1989. Fast and Robust Range Data Acquisition in a Low-Cost Environment. Proceedings der ISPRS Commission V Konferenz Close Range Photogrammetry Meets Machine Vision, Zürich. :496-503.
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1990. Recognition of Polyhedral Objects under Perspective View. Computers and Artificial Intelligence. 11:155–172.
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1992. Oberflächenvermessung mit einem 3D-Robotsensor. Zeitschrift für Photogrammetrie und Fererkundung (ZPF). :190-202.
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1990. Objekterkennung und Lagebestimmung mit einem 3D-Robotersensor. Tagungsband des 3. Symposiums Bildverarbeitung der Technischen Akademie Esslingen.
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1993. Three-Dimensional Range Acquisition of Line-Like Objects. Proceedings of the 3rd International Conference of Image Processingand its Applications University of Warwick, UK. :14-18.
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1989.