Current Challenges
- Improve productivity and supply chain efficiency in hazardous conditions.
- Prioritise health and safety by minimising long-duration tasks using robotics.
- Foster human-robot collaboration in everyday working environments.
- Develop multipurpose robots to address labor shortages.
- Enhance robotics data collection and analysis for improved decision-making.
- Implement human-like senses in robots for intelligent decision-making.
- Increase investment in AI and assess the return on investment.
- Promote scalability of AI-driven robotics for business integration.
- Align with the 2030 Climate Targets for energy efficiency and green job creation.
Objectives
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Develop a novel, pneumatic-based reconfigurable manipulator with advanced soft end-effectors capable of operating in environments with high risk of dust or water ingression while carrying out tasks involving both high forces/torques and delicate, complex manipulation
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Develop a Hierarchical Imitation Learning module, grounded on acquired knowledge alongside task planning algorithms with reactive planning capabilities including human-robot interaction
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Develop an Ontological framework for Knowledge Representation to enable robust and fault-tolerant collaboration and autonomous task completion through reasoning based on domain-specific fact understanding
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Develop a cognitive algorithm module encompassing Active Perception, Semantic Mapping and Localisation capabilities to fuse and orchestrate perception modalities in a dynamic context-aware that will enable identification changes in the environment and autonomous operation for longer periods while maintaining trustworthiness and dependability
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Establish an edge-native, resource-optimised and automated computing infrastructure able to support dynamic computing at the Cloud-Edge continuum realising an ecosystem where ML-models for new tasks and/or applications are efficiently updated deployed on-board the robot or in a distributed manner.
Expected Results
- Two reconfigurable pneumatic-based robotic manipulators mounted on a mobile robotic platform
- Novel soft end-effectors with variable stiffness that will allow for a diverse set of manipulation tasks
- A Robotic perception module comprising 3D vision algorithms
- A Localisation and Mapping module that allows the robot to accurately identify its position within the environment
- A Semantic Mapping module powered by scene understanding algorithms
- A Knowledge Representation framework that will capture important information regarding objects’ properties and relationships
- A Hierarchical Imitation Learning framework for acquiring robotic skills to accomplish complex tasks directly from human demonstrators
- A Human-Interaction conditioned Path and Task planning module enabling reactive robot control
- An edge-AI framework for deploying Machine Learning models and computer vision algorithms at the edge in a streamlined fashion
- Two demonstrators in solar and hydroponic farms