Development of Novel Polymer Optical Fiber Gratings. Polymer optical fiber gratings have attracted extensive worldwide research interest due to the excellent tunability and high sensitivity. They can be well developed into major devices for future optical communication and fiber sensing. But the research on polymer optical fiber are still at the early stage and the overall achievable performance of polymer optical fiber grating remains modest in comparison with that achieved in silica fiber grat ....Development of Novel Polymer Optical Fiber Gratings. Polymer optical fiber gratings have attracted extensive worldwide research interest due to the excellent tunability and high sensitivity. They can be well developed into major devices for future optical communication and fiber sensing. But the research on polymer optical fiber are still at the early stage and the overall achievable performance of polymer optical fiber grating remains modest in comparison with that achieved in silica fiber grating. This project addresses a range of key issues with scientific and technological importance on further exploring polymer optical fiber gratings for future industrial applications.Read moreRead less
Characterisation of soldered and adhesively bonded assemblies in photonic packages. Photonic packaging plays key roles in development of new optical technology. The project aims to establish the theories and techniques for characterising the integrity of soldered and adhesively bonded assemblies for photonic packaging. The critical failure mechanisms will be investigated, and sophisticated life prediction models will be established using artificial neural network (ANN) approaches for reliability ....Characterisation of soldered and adhesively bonded assemblies in photonic packages. Photonic packaging plays key roles in development of new optical technology. The project aims to establish the theories and techniques for characterising the integrity of soldered and adhesively bonded assemblies for photonic packaging. The critical failure mechanisms will be investigated, and sophisticated life prediction models will be established using artificial neural network (ANN) approaches for reliability assessment. The outcomes of the project will fill the gap in the knowledge for characterising failure processes of these assemblies and provide effective methods and easy-to-use guidelines
for reliability evaluation and life prediction of photonic packages, expanding and enhancing Australia's capacity in the areas.
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Optical Quantum Computation. The study of the storage, communication and processing of information stored in quantum systems - quantum information science - is recognized as key underpinning knowledge for future technologies. Technologies of current fundamental and popular interest such as quantum computation and teleportation are likely to form the basis of future communication and computation systems with far greater power and versatility than those of today. Having a stakehold in the developm ....Optical Quantum Computation. The study of the storage, communication and processing of information stored in quantum systems - quantum information science - is recognized as key underpinning knowledge for future technologies. Technologies of current fundamental and popular interest such as quantum computation and teleportation are likely to form the basis of future communication and computation systems with far greater power and versatility than those of today. Having a stakehold in the development of these technologies will be of significant national benefit for Australia.Read moreRead less
Engineered optical fibre device structures for next generation telecommunication systems. The next generation of optical telecommunication networks requires novel photonic compnents that are superior to current devices, and cannot be obtained by incremental improvement. This project will identify novel device architectures and implement these in practical devices. This will ensure that Australia remains at the cutting edge of photonics research, one of the most dynamic and exciting ereas in sc ....Engineered optical fibre device structures for next generation telecommunication systems. The next generation of optical telecommunication networks requires novel photonic compnents that are superior to current devices, and cannot be obtained by incremental improvement. This project will identify novel device architectures and implement these in practical devices. This will ensure that Australia remains at the cutting edge of photonics research, one of the most dynamic and exciting ereas in science and engineering and at the basis of a multibillion dollar industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883038
Funder
Australian Research Council
Funding Amount
$160,000.00
Summary
Upgrade key fabrication equipment for specialty fibre and device research and development. Australia remains a world leader in enabling technologies spanning information and communication, lasers, photonic sensing and diagnostics and much more. Underpinning much of this have been key backbone facilities at UNSW and at Sydney. Optical fibre research internationally is moving in new directions and for Australia to continue its leadership role, dedicated facilities for new generation structured opt ....Upgrade key fabrication equipment for specialty fibre and device research and development. Australia remains a world leader in enabling technologies spanning information and communication, lasers, photonic sensing and diagnostics and much more. Underpinning much of this have been key backbone facilities at UNSW and at Sydney. Optical fibre research internationally is moving in new directions and for Australia to continue its leadership role, dedicated facilities for new generation structured optical fibres, which are already impacting much more significantly than conventional fibres, must be available. The upgrade at UNSW will position Australia to continue its leadership and introduce educational and vocational training for the new industries that will depend on these core technologies. Read moreRead less
Next Generation Planar Tellurite Waveguides. The project provides the basis for the production of new high technology photonic products in Australia, the availability of at least one new unique facility for future scientific endeavour, and the generation of skillsets new to Australia. New IP will also be developed during the project. A successful outcome could also ultimately result in new products offering, for example, enhanced National Security through the Defence applications, better measure ....Next Generation Planar Tellurite Waveguides. The project provides the basis for the production of new high technology photonic products in Australia, the availability of at least one new unique facility for future scientific endeavour, and the generation of skillsets new to Australia. New IP will also be developed during the project. A successful outcome could also ultimately result in new products offering, for example, enhanced National Security through the Defence applications, better measurements of atmospheric contaminants through the sensing route, and more advanced telecommunications services at lower cost for citizens and businesses, and for lower operating costs for service providers.
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Multiple-input multiple-output orthogonal frequency division multiplexing (MIMO-OFDM) for optical wireless: a breakthrough solution to gaps in broadband delivery. Reliable, flexible broadband delivery is critical for Australian business and for the Australian community. This project will develop the technology on which a new generation of optical wireless communication systems will be based. By using optical rather than radio frequencies they will combine the data rates of optical with the mobil ....Multiple-input multiple-output orthogonal frequency division multiplexing (MIMO-OFDM) for optical wireless: a breakthrough solution to gaps in broadband delivery. Reliable, flexible broadband delivery is critical for Australian business and for the Australian community. This project will develop the technology on which a new generation of optical wireless communication systems will be based. By using optical rather than radio frequencies they will combine the data rates of optical with the mobility of wireless. They will fill many of the gaps in existing broadband delivery including providing a new flexible last-mile technology and an alternative form of local area network for indoor use. They will lead to new business opportunities within Australia and provide excellent research training in the field of OFDM, a field in which there is significant local R&D in Australian and multinational companies.Read moreRead less
New Photonics-based Interference Mitigation Filters for Radioastronomy. This project aims to study new topologies for photonics-based interference mitigation filters for radioastronomy. Its significance is that it will solve, for the first time, the problem of excising RF interfering signals from within the optical signal fibre transport systems conveying radioastronomy signals from phased array antennas. These interference suppressors are key elements in removing strong unwanted man-made signal ....New Photonics-based Interference Mitigation Filters for Radioastronomy. This project aims to study new topologies for photonics-based interference mitigation filters for radioastronomy. Its significance is that it will solve, for the first time, the problem of excising RF interfering signals from within the optical signal fibre transport systems conveying radioastronomy signals from phased array antennas. These interference suppressors are key elements in removing strong unwanted man-made signals from terrestrial transmitters and satellites that coexist, and make the detection of the very weak radioastronomy signals extremely difficult. The outcome will be new high-resolution and tunable fibre-based interference suppression filters integrable with the signal transport system, which enhance the sensitivity of radioastronomy phased arrays.Read moreRead less
Adaptive optical devices by microstructuring of nanocomposite materials. This project will develop novel nanocomposite materials and use them to fabricate adaptive optical devices designed and fabricated using innovative methods. Specifically, we will develop and characterise transparent composite materials comprising a dispersion of nano-sized inclusions within a polymer host. The properties of these materials will be tailored to allow fabrication of adaptive optical devices (e.g. tunable filte ....Adaptive optical devices by microstructuring of nanocomposite materials. This project will develop novel nanocomposite materials and use them to fabricate adaptive optical devices designed and fabricated using innovative methods. Specifically, we will develop and characterise transparent composite materials comprising a dispersion of nano-sized inclusions within a polymer host. The properties of these materials will be tailored to allow fabrication of adaptive optical devices (e.g. tunable filters and optical switches), which will be key components in future high-performance optical systems. Inverse scattering design methods will be extended to design two-dimensional bandgap devices which will be fabricated by microstructuring of the composite polymer materials.Read moreRead less
Verification and prototypes of Opto-ULSI Processors for MicroPhotonic Applications. The aim of the program is to establish efficient linkage between Australia and Korea by stimulating research towards the rapid integration of VLSI systems into photonic components, hence creating a new platform in intelligent MicroPhotonic systems, which are core elements for future-generation reconfigurable telecommunication networks. Our ultimate target is to (1) design a low-power 256-phase Opto-ULSI processor ....Verification and prototypes of Opto-ULSI Processors for MicroPhotonic Applications. The aim of the program is to establish efficient linkage between Australia and Korea by stimulating research towards the rapid integration of VLSI systems into photonic components, hence creating a new platform in intelligent MicroPhotonic systems, which are core elements for future-generation reconfigurable telecommunication networks. Our ultimate target is to (1) design a low-power 256-phase Opto-ULSI processor, (2) experimentally verify various reconfigurable MicroPhotonic architectures for optical telecommunication applications, (3) develop efficient software for the various MicroPhotonic systems, and (4) develop and verify working prototypes.Read moreRead less