Coding for Distributed Storage: Fundamental Limits and Code Designs. Applications such as file sharing, large-scale scientific projects, and social networking are fuelling the need for reliable and sustainable distributed storage systems. This project aims to develop the theory and the code designs for next-generation storage systems that are specifically optimised for the storage needs in such applications. This project is well placed to provide cost-effective, home-grown solutions for Australi ....Coding for Distributed Storage: Fundamental Limits and Code Designs. Applications such as file sharing, large-scale scientific projects, and social networking are fuelling the need for reliable and sustainable distributed storage systems. This project aims to develop the theory and the code designs for next-generation storage systems that are specifically optimised for the storage needs in such applications. This project is well placed to provide cost-effective, home-grown solutions for Australia's future data centre needs. Its potential immediate benefits are: contribution to the knowledge base and fundamental capabilities in storage systems; practical codes tailor-made for different storage applications; IP creation and commercialisation; and, education of future Australian academic and industrial innovators.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100752
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Fully-integrated fibre-based platform for a quantum information network. This project aims to combine Australia’s pioneering work developing specialised atom-filled optical fibres with world-leading quantum information storage protocols to probe the extreme limits of atom-light interactions. This will enable the creation of a compact, robust and modular node to efficiently store and process packets of optical quantum information. The node will integrate directly with current communications infra ....Fully-integrated fibre-based platform for a quantum information network. This project aims to combine Australia’s pioneering work developing specialised atom-filled optical fibres with world-leading quantum information storage protocols to probe the extreme limits of atom-light interactions. This will enable the creation of a compact, robust and modular node to efficiently store and process packets of optical quantum information. The node will integrate directly with current communications infrastructure, enabling the creation of a quantum Internet - the vital missing ingredient needed to overcome experimental hurdles that limit quantum technologies. This project is expected to enable the rapid uptake of quantum technology, boosting Australia’s capacity in this burgeoning field.Read moreRead less
Polymer fibres: A game changer for THz high-capacity interconnects. The transition to a society with consuming enormous amounts of digital data has accentuated the need for high-speed data links. The project aims to create a novel class of polymer terahertz fibres to replace the current lossy wires that are bandwidth limited. This will be achieved through innovative microstructured fibre designs, cost-effective and scalable fibre fabrication, and integration of terahertz fibre in the next genera ....Polymer fibres: A game changer for THz high-capacity interconnects. The transition to a society with consuming enormous amounts of digital data has accentuated the need for high-speed data links. The project aims to create a novel class of polymer terahertz fibres to replace the current lossy wires that are bandwidth limited. This will be achieved through innovative microstructured fibre designs, cost-effective and scalable fibre fabrication, and integration of terahertz fibre in the next generation communication systems. The project outcomes are expected to put Australia at the forefront of the field of polymer terahertz fibre links, which will be a game changer for industries that require reliable and high-speed connections including telecom, automotive, space, datacentres, and image processing.
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A Novel Inline High-Efficiency Motor/Pump System. Around 19% of the world’s and 30% of the Australia’s electric energy is consumed by pump technologies. Significant energy savings are possible if the major components of pump systems, including inverter, motor and pump, operate at their maximum possible efficiency under varying loads. A novel pump design in this project accommodates integrated electronics in a submersible housing. A seal-less design helps mitigate several aspects of pump failure ....A Novel Inline High-Efficiency Motor/Pump System. Around 19% of the world’s and 30% of the Australia’s electric energy is consumed by pump technologies. Significant energy savings are possible if the major components of pump systems, including inverter, motor and pump, operate at their maximum possible efficiency under varying loads. A novel pump design in this project accommodates integrated electronics in a submersible housing. A seal-less design helps mitigate several aspects of pump failure and its in-line structure reduces assembly cost. Accurately measured efficiency maps will be utilised to demonstrate the non-linear relationship between motor and pump quantities as well as developing models for indirectly estimating feedback quantities and achieving the highest system efficiency.Read moreRead less
Unconventional antennas from macro- to nano-scales. This research project will develop unconventional radio-frequency antennas for tomorrow's miniaturised multi-function wireless communication systems. It will also extend the principles to resonant nano-structures or 'optical antennas' which offer new perspectives in sensing physics, with the possibility of single molecule detection and identification.
Creating a national time and frequency network for Australia. This project will develop the means to distribute accurate time and frequency across the Australian continent via an optical fibre network. This network will meet the needs of future telecommunications, science and astronomy projects including the Australian bid for the Square Kilometre Array radio-astronomy project.
Reconfigurable polymer antennas. This research will utilise conductive polymers, or 'synthetic metals', as flexible and smart materials for radio-frequency antennas technology. The created antenna prototypes will find applications in biomedical devices (for example, for wearable devices and implants), for tagging (identification), and in reconfigurable antennas for wireless communication.