Abstract
Algorithms based on deep network models are being used for many pattern recognition and decision-making tasks in robotics and AI. Training these models requires a large labeled dataset and considerable computational resources, which are not readily available in many domains. Also, it is difficult to understand the internal representations and reasoning mechanisms of these models. The architecture described in this paper attempts to address these limitations by drawing inspiration from research in cognitive systems. It uses non-monotonic logical reasoning with incomplete commonsense domain knowledge, and inductive learning of previously unknown constraints on the domain’s states, to guide the construction of deep network models based on a small number of relevant training examples. As a motivating example, we consider a robot reasoning about the stability and partial occlusion of configurations of objects in simulated images. Experimental results indicate that in comparison with an architecture based just on deep networks, our architecture improves reliability, and reduces the sample complexity and time
complexity of training deep networks.
complexity of training deep networks.
Original language | English |
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Title of host publication | Robotics |
Subtitle of host publication | Science and Systems XV |
Editors | Antonio Bicchi, Hadas Kress-Gazit, Seth Hutchinson |
Publisher | Robotics: Science and Systems |
Number of pages | 10 |
ISBN (Electronic) | 978-0-9923747-5-4 |
ISBN (Print) | 978-0-9923747-5-4 |
DOIs | |
Publication status | Published - 23 Jun 2019 |
Event | Robotics: Science and Systems XV - Messe Freiburg, Freiburg, Germany Duration: 22 Jun 2019 → 26 Jun 2019 |
Publication series
Name | Robotics: Science and Systems Proceedings |
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Volume | 15 |
ISSN (Electronic) | 2330-765X |
Conference
Conference | Robotics |
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Abbreviated title | RSS 2019 |
Country/Territory | Germany |
City | Freiburg |
Period | 22/06/19 → 26/06/19 |
Keywords
- Commonsense reasoning
- deep learning