Coherent Optical Orthogonal Frequency-Division Multiplexing. Coherent optical orthogonal frequency-division multiplexing (CO-OFDM) incorporates the benefits of OFDM to compensate for distortion and monitor the channel conditions in long-haul optical links. The advantages of CO-OFDM can help meet the challenges of future optical networks that Australia depends upon for its information infrastructure and economic growth. Australia is currently at the forefront of optical OFDM technology, and the ....Coherent Optical Orthogonal Frequency-Division Multiplexing. Coherent optical orthogonal frequency-division multiplexing (CO-OFDM) incorporates the benefits of OFDM to compensate for distortion and monitor the channel conditions in long-haul optical links. The advantages of CO-OFDM can help meet the challenges of future optical networks that Australia depends upon for its information infrastructure and economic growth. Australia is currently at the forefront of optical OFDM technology, and the continuation of these research activities will further improve Australia's international ICT reputation. Furthermore, in the course of the project, a senior research associate and multiple highly-skilled students will be trained and exposed to techniques and innovations in this exciting field.Read moreRead less
Optical Multiple-Input Multiple-Output Communication Systems. Optical multiple-input multiple-output (MIMO) systems exploit a simple yet powerful principle of diversity to improve the capacity and robustness of optical networks. This proposal focuses on making the most use of two polarisation modes intrinsic to the fiber by applying MIMO techniques to the optical communication systems. This project can potentially create many commercial opportunities in Australia in the area of integrated photon ....Optical Multiple-Input Multiple-Output Communication Systems. Optical multiple-input multiple-output (MIMO) systems exploit a simple yet powerful principle of diversity to improve the capacity and robustness of optical networks. This proposal focuses on making the most use of two polarisation modes intrinsic to the fiber by applying MIMO techniques to the optical communication systems. This project can potentially create many commercial opportunities in Australia in the area of integrated photonic circuits and high-speed digital signal processing. The funding support of these research activities will further enhance Australia's international ICT reputation in this emerging field.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668381
Funder
Australian Research Council
Funding Amount
$750,000.00
Summary
Foundational National Nanotechnology Infrastructure. Breakthough nanotechnologies based on quantum mechanics promise useful devices for absolutely secure transmission of information encoded in quantum states, ultra-rapid searching through genome databases for unique gene sequences, faster electronic and photonic devices, robust devices made from diamond and better processing of biomedical materials for diagnosis of illness. Fabrication and characterization of these devices provides training for ....Foundational National Nanotechnology Infrastructure. Breakthough nanotechnologies based on quantum mechanics promise useful devices for absolutely secure transmission of information encoded in quantum states, ultra-rapid searching through genome databases for unique gene sequences, faster electronic and photonic devices, robust devices made from diamond and better processing of biomedical materials for diagnosis of illness. Fabrication and characterization of these devices provides training for research students in state-of-the-art techniques with many uses. Deeper understanding of these quantum technologies will lead to better models for some of the most puzzling aspects of quantum mechanical systems that are the foundation of the physical processes of
our universe.Read moreRead less
Low energy all-optical logic gates with improved cascadability and fan-out for future optical communications and signal processing systems. All-optical logic processing is the key to overcoming electronic bottlenecks in high-speed communication networks as single-channel speeds exceed electronic capabilities. This research will build off and extend Australia's world leading specialty fibre and fibre device capabilities and place Australia at the forefront in the international all-optical digital ....Low energy all-optical logic gates with improved cascadability and fan-out for future optical communications and signal processing systems. All-optical logic processing is the key to overcoming electronic bottlenecks in high-speed communication networks as single-channel speeds exceed electronic capabilities. This research will build off and extend Australia's world leading specialty fibre and fibre device capabilities and place Australia at the forefront in the international all-optical digital information-processing race. High quality research publications will enhance Australia's strong research reputation in photonics and advanced materials and promote international collaboration. New optical processing capabilities will benefit other application areas such as sensing and security.Read moreRead less
Nano-Engineered Glass for Next Generation Optical Fibre Devices and Systems. Optical fibre and fibre devices are a major technology platform of the IT revolution. The global photonics market is valued at $220bn, with Australian industry contributing ~$500m to the Australian economy. $158m is from communications photonics companies, largely SMEs, and comprises roughly 1% of the global telecoms photonic market. For Australia to be a significant player in this very competitive environment, the indu ....Nano-Engineered Glass for Next Generation Optical Fibre Devices and Systems. Optical fibre and fibre devices are a major technology platform of the IT revolution. The global photonics market is valued at $220bn, with Australian industry contributing ~$500m to the Australian economy. $158m is from communications photonics companies, largely SMEs, and comprises roughly 1% of the global telecoms photonic market. For Australia to be a significant player in this very competitive environment, the industry needs a continuing flow of research innovations. The breakthrough science in this research project will extend Australia's world leading speciality fibre and fibre device capabilities and the innovation will succour the growing Australian industry, ensuring a place on the next wave of deployment of photonic technology.Read moreRead less
Active Control of Light for Nonlinear Photonic Devices. In free space, light travels in a straight line, but since ancient times mankind has always sought to direct its propagation. Controlling light is an enduring problem in modern photonic technologies. The ultimate goal is to actively manipulate light propagation in space and time with a great accuracy. With this project we will investigate the fundamental science of active control of light in periodic structures and will provide a unique pla ....Active Control of Light for Nonlinear Photonic Devices. In free space, light travels in a straight line, but since ancient times mankind has always sought to direct its propagation. Controlling light is an enduring problem in modern photonic technologies. The ultimate goal is to actively manipulate light propagation in space and time with a great accuracy. With this project we will investigate the fundamental science of active control of light in periodic structures and will provide a unique platform for exploration of ground breaking optical physics, ensuring Australia remains a world leader in the field. Precision manipulation of light will form the basis of new techniques for all-optical signal processing and computing, with great impact on Australian photonic and defense industries.Read moreRead less
Ultra-sensitivity through resonances in photonic bandgap fibres. The project will develop innovative biochemical sensors with extreme sensitivity using recently discovered physical processes in novel holey optical fibres. These sensors will be able to detect biological molecules, toxins or dangerous chemicals in minute concentrations, in very small sample sizes. The sensors can be mass-produced cheaply with current fabrication facilities within Australia, enabling their widespread use for water ....Ultra-sensitivity through resonances in photonic bandgap fibres. The project will develop innovative biochemical sensors with extreme sensitivity using recently discovered physical processes in novel holey optical fibres. These sensors will be able to detect biological molecules, toxins or dangerous chemicals in minute concentrations, in very small sample sizes. The sensors can be mass-produced cheaply with current fabrication facilities within Australia, enabling their widespread use for water quality monitoring, environmental monitoring, threat detection, and rapid and reliable diagnosis in medicine.Read moreRead less
Special Research Initiatives - Grant ID: SR0567533
Funder
Australian Research Council
Funding Amount
$120,000.00
Summary
Scientific Instruments as ICT Components in Building a GrEMLIN for e-Research. The proposal seeks to initiate the development of a GrEMLIN, a Grid Enabled Multi-Level Instrument Network, for e-Research. Scientific instruments, whether at conventional laboratories or at major facilities, may be regarded as specialised ICT components in a network providing remote access to such instrumentation. Collaborative remote access and data analysis brings efficiency and effectiveness dividends, that can ....Scientific Instruments as ICT Components in Building a GrEMLIN for e-Research. The proposal seeks to initiate the development of a GrEMLIN, a Grid Enabled Multi-Level Instrument Network, for e-Research. Scientific instruments, whether at conventional laboratories or at major facilities, may be regarded as specialised ICT components in a network providing remote access to such instrumentation. Collaborative remote access and data analysis brings efficiency and effectiveness dividends, that can be enhanced through the harnessing of Grid technologies. The collaborative project will leverage middleware, Web Services and e-Science software developments in the US and UK, to provide Grid enabled remote instrument access and data analysis as a powerful e-Research tool.Read moreRead less
Light control in nonlinear periodic structures. New technologies for precise control of light in microstructured periodic materials hold promises for breakthroughs in all-optical computing and communication areas. This project will develop novel concepts and innovative techniques to dynamically induce periodic structures in highly nonlinear materials for active control of light by light itself. It will combine experiment and theory to reveal and engineer the key aspects of light propagation in t ....Light control in nonlinear periodic structures. New technologies for precise control of light in microstructured periodic materials hold promises for breakthroughs in all-optical computing and communication areas. This project will develop novel concepts and innovative techniques to dynamically induce periodic structures in highly nonlinear materials for active control of light by light itself. It will combine experiment and theory to reveal and engineer the key aspects of light propagation in these structures, such as beam shaping and interactions. The outcome of this fundamental research will open-up new directions for technological advances in the photonics industry, with applications in all-optical switching and information storage.Read moreRead less