Biologically-inspired SLAM: Where are we coming from and where could we go?
In this talk, I will present an objective take on opportunities and mysteries in the area of biologically inspired mapping and navigation for robotics, that also recognizes the practical realities and requirements of modern-day SLAM applications. In particular, I will discuss five key questions and open research areas in the bio-inspired mapping, navigation, and SLAM area, linking into past and recent neuroscience and biological discoveries: The Loop Closure Question, The 3D Question, The Probabilistic Question, The Multi-Scale Question, and The Behavioural Question.
Bio: Professor Milford conducts interdisciplinary research at the boundary between robotics, neuroscience and computer vision and is a multi-award winning educational entrepreneur. His research models the neural mechanisms in the brain underlying tasks like navigation and perception to develop new technologies in challenging application domains such as all-weather, anytime positioning for autonomous vehicles. He is also passionate about engaging and educating all sectors of society around new opportunities and impacts from technology including robotics, autonomous vehicles and artificial intelligence. Michael currently holds the positions of Australian Research Council Laureate Fellow, Joint Director of the QUT Centre for Robotics, QUT Professor, Microsoft Research Faculty Fellow and is a former Chief Investigator at the Australian Centre for Robotic Vision.
Developmental Robotics for Language Learning, Trust and Theory of Mind
Growing theoretical and experimental research on action and language processing and on number learning and gestures clearly demonstrates the role of embodiment in cognition and language processing. In psychology and neuroscience, this evidence constitutes the basis of embodied cognition, also known as grounded cognition (Pezzulo et al. 2012). In robotics and AI, these studies have important implications for the design of linguistic capabilities in cognitive agents and robots for human-robot collaboration, and have led to the new interdisciplinary approach of Developmental Robotics, as part of the wider Cognitive Robotics field (Cangelosi & Schlesinger 2015; Cangelosi & Asada 2021). During the talk, we will present examples of developmental robotics models and experimental results from iCub experiments on the embodiment biases in early word acquisition and grammar learning (Morse et al. 2015; Morse & Cangelosi 2017) and experiments on pointing gestures and finger counting for number learning (De La Cruz et al. 2014). We will then present a novel developmental robotics model, and experiments, on Theory of Mind and its use for autonomous trust behavior in robots (Vinanzi et al. 2019). The implications for the use of such embodied approaches for embodied cognition in AI and cognitive sciences, and for robot companion applications will also be discussed.
Angelo Cangelosi is a Professor of Machine Learning and Robotics at the University of Manchester (UK), where he leads the Cognitive Robotics Lab. He also is Turing Fellow at the Alan Turing Institute London, Visiting Professor at Hohai University and at Universita’ Cattolica Milan and Turin University, and Visiting Distinguished Fellow at AIST-AIRC Tokyo. His research interests are in developmental robotics, language grounding, human robot-interaction and trust, and robot companions for health and social care. Cangelosi is Editor of the journals Interaction Studies and IET Cognitive Computation and Systems, and in 2015 was Editor-in-Chief of IEEE Transactions on Autonomous Development. His book “Developmental Robotics: From Babies to Robots” (MIT Press) was published in January 2015 and recently translated into Chinese and Japanese. His latest book “Cognitive Robotics” (MIT Press), coedited with Minoru Asada, will be published in 2022.
Speech Title: Streamlining Aircraft via Multidisciplinary Design Optimization
More speakers info. will be released soon.