Design automation for secure, reliable and energy efficient embedded processors. This project seeks to create a methodology to design and generate processors which are both secure, reliable and energy efficient for deployment in Internet of Things (IoT) systems, which require little on-going maintenance. In such systems, both security and reliability are paramount, particularly in medical devices, control devices in critical machinery, financial transactions and automotive electronics. The proje ....Design automation for secure, reliable and energy efficient embedded processors. This project seeks to create a methodology to design and generate processors which are both secure, reliable and energy efficient for deployment in Internet of Things (IoT) systems, which require little on-going maintenance. In such systems, both security and reliability are paramount, particularly in medical devices, control devices in critical machinery, financial transactions and automotive electronics. The project will use an open RISC-V processor which is sufficiently flexible to function as a base processor, with a myriad of tools such as compilers and debuggers available. Reliable computing machinery will enable systems to work in hostile environments and be functionally correct for longer.Read moreRead less
Custom Computing for DNA Analysis of Third Generation Sequencers. The project aims to create a Domain Specific Computing System to analyse data emerging from third-generation DNA sequencers. The significance is that such a system will enable in-situ analysis, facilitating far wider deployment of modern DNA technologies. The expected outcome will be a portable low-power computing system containing custom instructions, custom cache configurations, and custom architectures. Benefits include: 1. d ....Custom Computing for DNA Analysis of Third Generation Sequencers. The project aims to create a Domain Specific Computing System to analyse data emerging from third-generation DNA sequencers. The significance is that such a system will enable in-situ analysis, facilitating far wider deployment of modern DNA technologies. The expected outcome will be a portable low-power computing system containing custom instructions, custom cache configurations, and custom architectures. Benefits include: 1. deployment of DNA analysis techniques in remote areas and in places without large servers and access to high-speed networks connecting to cloud servers; 2. quicker analysis enabling rapid response, cheaper, portable systems; and, 3. training for a cohort of research and honours students.Read moreRead less