Cognition and learning involve processes operating all the way from the molecular level to large networks of interconnected neurons, spanning nine orders of magnitude and involving electrical, chemical, and mechanical signals. To begin to understand how these complex processes operate requires interdisciplinary teams bringing skills and techniques from fields such as neuroscience, psychology, psychiatry, artificial intelligence, statistics, imaging, genetics, engineering and mathematical modelling.
The physical sciences have their foundations firmly based in mathematical modelling. And modelling has facilitated many advances including enabling the development of complex systems that exhibit levels of artificial intelligence. For instance, in electrical engineering, multi-scale modelling techniques permit us to model and build complex systems of transistors, acting in unison, which can beat humans at games such as 'Jeopardy'. These multi-scale models include models of transistors, nanoscale devices of a few thousand atoms operating at the quantum mechanical level; to circuits, comprising a few hundred to a few thousand transistors, that aggregate and process signals to produce complex outputs; to systems of circuits that interact with their environment (including humans) and generate higher order outputs.
The group will discuss questions such as:
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