A Two-Layered Approach to Adaptive Dialogues for Robotic Assistance
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Amedeo Cesta | Andrea Orlandini | Alessandro Umbrico | Gabriella Cortellessa | Francesca Fracasso | Riccardo De Benedictis | A. Cesta | Andrea Orlandini | Gabriella Cortellessa | Francesca Fracasso | A. Umbrico | Riccardo De Benedictis
[1] Filip Karlo Dosilovic,et al. Explainable artificial intelligence: A survey , 2018, 2018 41st International Convention on Information and Communication Technology, Electronics and Microelectronics (MIPRO).
[2] Pat Langley,et al. Cognitive architectures: Research issues and challenges , 2009, Cognitive Systems Research.
[3] Amedeo Cesta,et al. A Holistic Approach to Behavior Adaptation for Socially Assistive Robots , 2020, Int. J. Soc. Robotics.
[4] C. Nass,et al. Does computer-synthesized speech manifest personality? Experimental tests of recognition, similarity-attraction, and consistency-attraction. , 2001, Journal of experimental psychology. Applied.
[5] David Vernon,et al. The role of cognitive architectures in general artificial intelligence , 2018, Cognitive Systems Research.
[6] Alex Mihailidis,et al. Learning and Personalizing Socially Assistive Robot Behaviors to Aid with Activities of Daily Living , 2018, ACM Transactions on Human-Robot Interaction.
[7] N. Guarino,et al. Formal Ontology in Information Systems : Proceedings of the First International Conference(FOIS'98), June 6-8, Trento, Italy , 1998 .
[8] Doina Precup,et al. Between MDPs and Semi-MDPs: A Framework for Temporal Abstraction in Reinforcement Learning , 1999, Artif. Intell..
[9] Amedeo Cesta,et al. Toward intelligent continuous assistance , 2020, J. Ambient Intell. Humaniz. Comput..
[10] Marta Cialdea Mayer,et al. Planning and execution with flexible timelines: a formal account , 2016, Acta Informatica.
[11] Alessandro Saffiotti,et al. Towards a science of integrated AI and Robotics , 2017, Artif. Intell..
[12] Joelle Pineau,et al. The Bottleneck Simulator: A Model-based Deep Reinforcement Learning Approach , 2018, J. Artif. Intell. Res..
[13] Amedeo Cesta,et al. Training for crisis decision making - An approach based on plan adaptation , 2014, Knowl. Based Syst..
[14] Amedeo Cesta,et al. PLATINUm: A New Framework for Planning and Acting , 2017, AI*IA.
[15] Yuandong Tian,et al. Algorithmic Framework for Model-based Deep Reinforcement Learning with Theoretical Guarantees , 2018, ICLR.
[16] Silvia Rossi,et al. User profiling and behavioral adaptation for HRI: A survey , 2017, Pattern Recognit. Lett..
[17] D Feil-Seifer,et al. Socially Assistive Robotics , 2011, IEEE Robotics & Automation Magazine.
[18] D. Feil-Seifer,et al. Defining socially assistive robotics , 2005, 9th International Conference on Rehabilitation Robotics, 2005. ICORR 2005..
[19] Moritz Tenorth,et al. Representations for robot knowledge in the KnowRob framework , 2017, Artif. Intell..
[20] Dieter Fensel,et al. Knowledge Engineering: Principles and Methods , 1998, Data Knowl. Eng..
[21] Sergey Levine,et al. SOLAR: Deep Structured Representations for Model-Based Reinforcement Learning , 2018, ICML.
[22] Brian Scassellati,et al. Socially assistive robotics [Grand Challenges of Robotics] , 2007, IEEE Robotics & Automation Magazine.
[23] John K. Tsotsos,et al. 40 years of cognitive architectures: core cognitive abilities and practical applications , 2018, Artificial Intelligence Review.
[24] Malik Ghallab,et al. Deliberation for autonomous robots: A survey , 2017, Artif. Intell..
[25] Adriana Tapus,et al. User—robot personality matching and assistive robot behavior adaptation for post-stroke rehabilitation therapy , 2008, Intell. Serv. Robotics.