A Learning-based Control Architecture for Socially Assistive Robots Providing Cognitive Interventions

Chan, Jeanie

05 December 2011

Due to the world’s rapidly growing elderly population, dementia is becoming increasingly prevalent. This poses considerable health, social, and economic concerns as it impacts individuals, families and healthcare systems. Current research has shown that cognitive interventions may slow the decline of or improve brain functioning in older adults. This research investigates the use of intelligent socially assistive robots to engage individuals in person-centered cognitively stimulating activities. Specifically, in this thesis, a novel learning-based control architecture is developed to enable socially assistive robots to act as social motivators during an activity. A hierarchical reinforcement learning approach is used in the architecture so that the robot can learn appropriate assistive behaviours based on activity structure and personalize an interaction based on the individual’s behaviour and user state. Experiments show that the control architecture is effective in determining the robot’s optimal assistive behaviours for a memory game interaction and a meal assistance scenario.

Human-robot Interaction

Control Architecture

Robotics

Hierarchical Reinforcement Learning

Multi-modal Human-machine Interfaces

Cognitive Interventions

Socially Assistive Robots

0771

0800

0548

A Learning-based Control Architecture for Socially Assistive Robots Providing Cognitive Interventions

Chan, Jeanie

05 December 2011

Due to the world’s rapidly growing elderly population, dementia is becoming increasingly prevalent. This poses considerable health, social, and economic concerns as it impacts individuals, families and healthcare systems. Current research has shown that cognitive interventions may slow the decline of or improve brain functioning in older adults. This research investigates the use of intelligent socially assistive robots to engage individuals in person-centered cognitively stimulating activities. Specifically, in this thesis, a novel learning-based control architecture is developed to enable socially assistive robots to act as social motivators during an activity. A hierarchical reinforcement learning approach is used in the architecture so that the robot can learn appropriate assistive behaviours based on activity structure and personalize an interaction based on the individual’s behaviour and user state. Experiments show that the control architecture is effective in determining the robot’s optimal assistive behaviours for a memory game interaction and a meal assistance scenario.

Human-robot Interaction

Control Architecture

Robotics

Hierarchical Reinforcement Learning

Multi-modal Human-machine Interfaces

Cognitive Interventions

Socially Assistive Robots

0771

0800

0548