Neurobiologically Inspired Robotics: Enhanced Autonomy through Neuromorphic Cognition

doi:10.1016/j.neunet.2015.11.004

Neural Networks

Volume 72, December 2015, Pages 1-2

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Cited by (5)

Visual attention and object naming in humanoid robots using a bio-inspired spiking neural network
2018, Robotics and Autonomous Systems
Citation Excerpt :
Because the nervous system is so closely coupled with the body and situated in the environment, brain-based robots can provide powerful tools for studying neural function, as they can be tested and probed in ways that are not yet achievable in human and animal experiments. Neurobiologically inspired systems present great potential to advance the field of autonomous robots and our understanding of the human brain [24]. Experiments in neurorobotics permit to progress in understanding how the interplay between neural learning dynamics, physical embodiment and environmental factors shape developmental trajectories [23].
Recent advances in behavioural and computational neuroscience, cognitive robotics, and in the hardware implementation of large-scale neural networks, provide the opportunity for an accelerated understanding of brain functions and for the design of interactive robotic systems based on brain-inspired control systems. This is especially the case in the domain of action and language learning, given the significant scientific and technological developments in this field. In this work we describe how a neuroanatomically grounded spiking neural network for visual attention has been extended with a word learning capability and integrated with the iCub humanoid robot to demonstrate attention-led object naming. Experiments were carried out with both a simulated and a real iCub robot platform with successful results. The iCub robot is capable of associating a label to an object with a ‘preferred’ orientation when visual and word stimuli are presented concurrently in the scene, as well as attending to said object, thus naming it. After learning is complete, the name of the object can be recalled successfully when only the visual input is present, even when the object has been moved from its original position or when other objects are present as distractors.
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EditorialNeurobiologically Inspired Robotics: Enhanced Autonomy through Neuromorphic Cognition

Neural Networks

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Neural Networks

Editorial
Neurobiologically Inspired Robotics: Enhanced Autonomy through Neuromorphic Cognition