Liquid light: aqueous bio-sensing in microstructured polymer optical fibres. This project builds on Australia's world-leading position in the development of microstructured polymer optical fibres, and applies the unique benefits they provide to for ultra- sensitive bio-sensing. By using the microstructure to simultaneously confine light and liquid, microstructured optical fibres provide a unique platform for ultra-sensitive spectroscopy and structural studies of biomolecules in solution. The wor ....Liquid light: aqueous bio-sensing in microstructured polymer optical fibres. This project builds on Australia's world-leading position in the development of microstructured polymer optical fibres, and applies the unique benefits they provide to for ultra- sensitive bio-sensing. By using the microstructure to simultaneously confine light and liquid, microstructured optical fibres provide a unique platform for ultra-sensitive spectroscopy and structural studies of biomolecules in solution. The work has profound implications both for fundamental science and applications, particularly in medical diagnostics.Read moreRead less
Novel coherence-free photonic microwave signal processors. With the increasing bandwidth requirements of information signals, there is an unprecedented challenge to provide high-speed and high resolution systems for signal processing. The new photonic signal processors in this project will herald in a new epoch in the ability to optimally condition wideband signals, with important applications for science, business and security services. These processors will have particular impact in transcendi ....Novel coherence-free photonic microwave signal processors. With the increasing bandwidth requirements of information signals, there is an unprecedented challenge to provide high-speed and high resolution systems for signal processing. The new photonic signal processors in this project will herald in a new epoch in the ability to optimally condition wideband signals, with important applications for science, business and security services. These processors will have particular impact in transcending exisiting electronic processor limitations and in enhancing fibre-fed distributed antenna systems, with benefits to Australia in the fields of radioastronomy and radar systems in defence.Read moreRead less
Novel coherence-free microwave photonic signal processors. With the unrelenting push for increasing bandwidth requirements, there is an unprecedented challenge to provide high-performance systems for high-bandwidth signal processing. In areas such as fibre-wireless networks, radioastronomy, and defence, it is essential to pre-process the wideband fibre-fed distributed antenna signals. The new coherence-free, high-frequency, low-noise photonic signal processors, in this project have important app ....Novel coherence-free microwave photonic signal processors. With the unrelenting push for increasing bandwidth requirements, there is an unprecedented challenge to provide high-performance systems for high-bandwidth signal processing. In areas such as fibre-wireless networks, radioastronomy, and defence, it is essential to pre-process the wideband fibre-fed distributed antenna signals. The new coherence-free, high-frequency, low-noise photonic signal processors, in this project have important applications for science, business and security services. The results have widespread uses in enhancing fibre-fed distributed antenna systems, with national benefits in the fields of radioastronomy and radar systems in defence.Read moreRead less
Dynamically tunable, low-noise, discrete-time optical processing of high-speed signals. In today's society there is an unrelenting push for increasing bandwidth requirements. Thus the challenge arises to provide systems that can optimally condition high-speed signals. Many systems carry not only the desired information but also high level interference signals. Tunable interference mitigation is required to address different interferers actively while having minimal impact on the passband. The ne ....Dynamically tunable, low-noise, discrete-time optical processing of high-speed signals. In today's society there is an unrelenting push for increasing bandwidth requirements. Thus the challenge arises to provide systems that can optimally condition high-speed signals. Many systems carry not only the desired information but also high level interference signals. Tunable interference mitigation is required to address different interferers actively while having minimal impact on the passband. The new dynamically tunable photonic signal processors in this project have important applications for science, business and security services. The results have widespread uses in enhancing fibre-fed distributed antenna systems, with national benefits in the fields of radioastronomy and radar systems in defence.Read moreRead less
New paradigms for high-resolution microwave photonic signal processing. In today's society there is an unrelenting push for increasing bandwidth requirements. Thus there are unprecedented challenges to provide systems that can optimally condition high-speed signals. Many systems carry not only the desired information but also high-level interference signals. Tunable interference mitigation is essential to address different interferers actively while having minimal impact on the required signal. ....New paradigms for high-resolution microwave photonic signal processing. In today's society there is an unrelenting push for increasing bandwidth requirements. Thus there are unprecedented challenges to provide systems that can optimally condition high-speed signals. Many systems carry not only the desired information but also high-level interference signals. Tunable interference mitigation is essential to address different interferers actively while having minimal impact on the required signal. The new dynamically reconfigurable photonic signal processors in this project have important applications for science, business and security services. The results have widespread uses in enhancing fibre-fed distributed antenna systems, with national benefits in the fields of radioastronomy and radar systems in defence.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
Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be ....Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be developed that will add to the nation's skill base. The outcomes of the project will enhance Australia's knowledge capacity, research capability and will contribute significantly to each of the National Research Priorities.Read moreRead less
Interferometric Distributed Feedback Fibre Laser Sensors. This project will solve important problems in realising next generation underwater optical fibre sensor systems for defence and marine exploration. OFTC's expertise in specialty optical fibre and devices will be combined with Thales' expertise in underwater sensor systems to give Australia a global lead. The benefits are commercial, national security and research standing. Domestic manufacture of a major optical system will assist maturat ....Interferometric Distributed Feedback Fibre Laser Sensors. This project will solve important problems in realising next generation underwater optical fibre sensor systems for defence and marine exploration. OFTC's expertise in specialty optical fibre and devices will be combined with Thales' expertise in underwater sensor systems to give Australia a global lead. The benefits are commercial, national security and research standing. Domestic manufacture of a major optical system will assist maturation of the sector which is dominated by component companies. This system for underwater surveillance is obviously important to a country with a large coastline to defend. This project will build Australia's global reputation renowned for research excellence in fibre and fibre devices.Read moreRead less
The creation and opimisation of new optical fibres and novel diode-pumped fibre lasers for applications in medicine, defence and the environment. The project will widen Australian laser research and contains the important steps required to progress beyond the recent demonstrations of super high power and ultra-compact mode-locked operation. The proposed fibre lasers are internationally significant, will address many applications and will keep Australia at the leading edge of laser and optical fi ....The creation and opimisation of new optical fibres and novel diode-pumped fibre lasers for applications in medicine, defence and the environment. The project will widen Australian laser research and contains the important steps required to progress beyond the recent demonstrations of super high power and ultra-compact mode-locked operation. The proposed fibre lasers are internationally significant, will address many applications and will keep Australia at the leading edge of laser and optical fibre research. The array of new technologies necessary for the development of the proposed lasers will be vitally important to Australia's high technology industries.Read moreRead less
Advanced Laser, Sensor and Diagnostic Technologies Using New Generation Micro- and Nano- Structured Fibres and Gratings. The project aims to provide the next generation of laser and sensor technologies, benefiting not only advanced instrument industries but also others involved with materials processing, sensing diagnostics, biomedicine and defence. The search for a universal model of light interactions with all photosensitive materials, coupled with a demonstration of nanotechnology within a fi ....Advanced Laser, Sensor and Diagnostic Technologies Using New Generation Micro- and Nano- Structured Fibres and Gratings. The project aims to provide the next generation of laser and sensor technologies, benefiting not only advanced instrument industries but also others involved with materials processing, sensing diagnostics, biomedicine and defence. The search for a universal model of light interactions with all photosensitive materials, coupled with a demonstration of nanotechnology within a fibre, will lead to new gratings and fibres that underpin these technologies as well as open up new techniques and processes such as practical radiation hardening of optical waveguides.Read moreRead less