Discovery Early Career Researcher Award - Grant ID: DE160101032
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Electronics of the future: self-powering wireless circuit design. The aim of this project is to build a foundation for ultra-low-power wireless circuit design using technologies other than silicon. Scaling of transistors in silicon has been pushed to its limit and is of marginal benefit for low-power wireless circuit design. This project aims to address these limits by developing energy-efficient technology for wireless applications. The intended outcome of this project will be a self-powered, h ....Electronics of the future: self-powering wireless circuit design. The aim of this project is to build a foundation for ultra-low-power wireless circuit design using technologies other than silicon. Scaling of transistors in silicon has been pushed to its limit and is of marginal benefit for low-power wireless circuit design. This project aims to address these limits by developing energy-efficient technology for wireless applications. The intended outcome of this project will be a self-powered, high data rate receiver that will be critical in 5th-generation wireless systems. This could be used for a range of innovative wireless applications, for example in health care and environmental monitoring.Read moreRead less
Autonomous body sensors in humans: investigating new bio-sensing techniques with self-power generation. Using advanced integrated electronic and mechanical systems, it is now possible to design small biomedical sensors that can be inserted into the body to take biological measurements. This project introduces a new kind of bio-sensors with self-energy generation capability and reduces the need for periodic battery replacement. New wireless and circuit techniques are investigated to reduce power ....Autonomous body sensors in humans: investigating new bio-sensing techniques with self-power generation. Using advanced integrated electronic and mechanical systems, it is now possible to design small biomedical sensors that can be inserted into the body to take biological measurements. This project introduces a new kind of bio-sensors with self-energy generation capability and reduces the need for periodic battery replacement. New wireless and circuit techniques are investigated to reduce power consumption and physical dimensions, while providing a better performance and a safer wireless link. The project aims to deliver high level of comfort, better mobility and better patient care.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100924
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Integrated Interconnects in Data Centres and High-Performance Computing. High-speed interconnects are needed to link, transmit, retrieve, and process intensive data in a time- and energy-efficient and cost-effective manner in data centres and high-performance computing. This project aims to investigate high-speed, integrated interconnects, including novel integrated devices and transceivers on silicon platforms, flexible subsystems and overall system architecture. The research outcomes will be b ....Integrated Interconnects in Data Centres and High-Performance Computing. High-speed interconnects are needed to link, transmit, retrieve, and process intensive data in a time- and energy-efficient and cost-effective manner in data centres and high-performance computing. This project aims to investigate high-speed, integrated interconnects, including novel integrated devices and transceivers on silicon platforms, flexible subsystems and overall system architecture. The research outcomes will be beneficial to a number of industries including integrated chip and circuit design and fabrication, integrated systems, and network infrastructures, and will enable faster platforms for cloud computing, sensing, signal processing, and computational health.Read moreRead less
Sustainability in Computing: A Holistic View. Green computing must provide sustainable processing capabilities with high energy efficiency (lower carbon footprint) and increased product longevity (reducing the need for product replacement). While advances in technology have afforded significant reduction in power requirements, they come with inherent challenges due to uncertainties in micro-scale behaviour, high complexity of quantifying/optimising energy cost or system lifetime in extreme scale ....Sustainability in Computing: A Holistic View. Green computing must provide sustainable processing capabilities with high energy efficiency (lower carbon footprint) and increased product longevity (reducing the need for product replacement). While advances in technology have afforded significant reduction in power requirements, they come with inherent challenges due to uncertainties in micro-scale behaviour, high complexity of quantifying/optimising energy cost or system lifetime in extreme scale computing, and the interaction of non-computing components with individual computing systems. This project addresses these challenges via a holistic, multi-scale paradigm for modelling, analysis, and optimisation of energy cost, carbon footprint, and product lifetime in emerging computing systems.Read moreRead less
Integrated energy conversion and management systems in silicon-on-sapphire. The aim of this research is to develop specialised "power-supply-on-a-chip" integrated circuits (ICs) for efficient conversion and management of electrical energy. The project will utilise and develop the unique local expertise and IC fabrication capability in silicon-on-sapphire technology in partnership with Sapphicon Semiconductor Pty. Ltd. The ICs developed will be used to improve the performance of small-scale elect ....Integrated energy conversion and management systems in silicon-on-sapphire. The aim of this research is to develop specialised "power-supply-on-a-chip" integrated circuits (ICs) for efficient conversion and management of electrical energy. The project will utilise and develop the unique local expertise and IC fabrication capability in silicon-on-sapphire technology in partnership with Sapphicon Semiconductor Pty. Ltd. The ICs developed will be used to improve the performance of small-scale electric power and transport systems based on alternative energy sources, thereby assisting energy self-sufficiency in rural and remote communities and reducing Australia's dependence on fossil and other non-renewable fuels. Sales of the ICs will also generate export income for Australian industry.Read moreRead less
A new spectrum access technology for future wireless terminals. This project will develop a new frequency flexible wireless transceiver structure for the next generation of smartphones and wireless devices. The project will improve the roaming experience of travellers and reduce the cost of wireless connectivity, enabling new applications such as machine-to-machine communications and the internet-of-things.
Hardware Acceleration for Neural Systems. To really understand how brains work, we need to simulate neural networks of a size similar to that of the human brain (100 billion neurons, 100 trillion connections). Simulating such a network on standard computers in not possible because of its sheer size. Several groups are currently building very expensive and proprietary hardware to solve this, but the output from these projects will not be accessible to other researchers. In order to make real prog ....Hardware Acceleration for Neural Systems. To really understand how brains work, we need to simulate neural networks of a size similar to that of the human brain (100 billion neurons, 100 trillion connections). Simulating such a network on standard computers in not possible because of its sheer size. Several groups are currently building very expensive and proprietary hardware to solve this, but the output from these projects will not be accessible to other researchers. In order to make real progress in neuroscience, many more researchers need to be enabled to participate. To do this, the project will build a system from commercial hardware (FPGAs) that will cost only a few ten thousand dollars and it will make this design and software available for free. Read moreRead less
Wearable device design with continuous cuff-less blood pressure measurement. This project aims to develop a non-invasive, body-worn device able to monitor blood pressure (BP) continuously in real time. The project proposes new sensing techniques for blood pressure measurement based on capturing pulse transit time in the central arteries using a combination of electrical bio-impedance, electrocardiogram (ECG), and continuous wave radar. Coupled with other vital parameters including heart rate, he ....Wearable device design with continuous cuff-less blood pressure measurement. This project aims to develop a non-invasive, body-worn device able to monitor blood pressure (BP) continuously in real time. The project proposes new sensing techniques for blood pressure measurement based on capturing pulse transit time in the central arteries using a combination of electrical bio-impedance, electrocardiogram (ECG), and continuous wave radar. Coupled with other vital parameters including heart rate, heart rhythm, respiratory rate, and oxygen saturation, it is expected that the device will enable remote monitoring with wireless connectivity and with many advantages over the traditional wired monitoring methods currently used in healthcare environments and it will assist with more effective prevention, home care and treatment.Read moreRead less
Designing Radiation-Tolerant Reconfigurable Systems for Space. The processing speed, cost and flexibility requirements of future satellite-based applications cannot be satisfied with conventional radiation-hardened processors or custom integrated circuits. This project aims to develop key technology to enable off-the-shelf hardware to be customised for this use without compromising reliability. The project aims to develop the design methods needed to implement a given set of satellite applicatio ....Designing Radiation-Tolerant Reconfigurable Systems for Space. The processing speed, cost and flexibility requirements of future satellite-based applications cannot be satisfied with conventional radiation-hardened processors or custom integrated circuits. This project aims to develop key technology to enable off-the-shelf hardware to be customised for this use without compromising reliability. The project aims to develop the design methods needed to implement a given set of satellite applications on a processing platform composed of application-specific soft processors and accelerator circuits hosted on conventional reconfigurable logic devices. Crucially, the solution architecture is expected to be sufficiently hardened against radiation-induced errors while meeting performance and circuit area constraints.Read moreRead less
Low cost, efficient and more reliable power switching network. This project aims to propose new power electronics circuit integration concepts and control techniques to reduce power supply cost by at least 30 per cent while improving efficiency and reliability. Photovoltaic combined battery storage application will be implemented and tested in detail to demonstrate the feasibility of the proposed concepts. The outcomes of the project will benefit many emerging technologies such as electric vehic ....Low cost, efficient and more reliable power switching network. This project aims to propose new power electronics circuit integration concepts and control techniques to reduce power supply cost by at least 30 per cent while improving efficiency and reliability. Photovoltaic combined battery storage application will be implemented and tested in detail to demonstrate the feasibility of the proposed concepts. The outcomes of the project will benefit many emerging technologies such as electric vehicles, renewable energy and energy storage systems, wireless communications and portable devices.Read moreRead less