Target Identification with Ultra-Wideband Polarimetric Radar. Radar reflecting objects resonate when electromagnetically and appropriately excited. These resonances can be extracted from the returned radar signal and used to identify the object. A simile is identifying a tuning fork from its sound rather than its image.
The techniques developed in this proposal are primarily to be used in security and defence applications for better screening of threat targets. The benefit is a safe and more ....Target Identification with Ultra-Wideband Polarimetric Radar. Radar reflecting objects resonate when electromagnetically and appropriately excited. These resonances can be extracted from the returned radar signal and used to identify the object. A simile is identifying a tuning fork from its sound rather than its image.
The techniques developed in this proposal are primarily to be used in security and defence applications for better screening of threat targets. The benefit is a safe and more secure environment. 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
Laboratory in a Fibre: diagnostic, sensing and telecommunications technologies. The lab-in-a-fibre aims to provide the next generation of diagnostic, sensing and telecommunications technologies. Mass production of km long optical fibre platforms for the lab-in-a-fibre offers cost competitive alternative to lab-on-a-chip technologies in applications where several diagnostic, sensing processes or component technologies are required. It will benefit not only advanced instrument industries but also ....Laboratory in a Fibre: diagnostic, sensing and telecommunications technologies. The lab-in-a-fibre aims to provide the next generation of diagnostic, sensing and telecommunications technologies. Mass production of km long optical fibre platforms for the lab-in-a-fibre offers cost competitive alternative to lab-on-a-chip technologies in applications where several diagnostic, sensing processes or component technologies are required. It will benefit not only advanced instrument industries but also others involved with materials processing, sensing diagnostics, biomedicine and defence. The overall integration within the program will provide the mechanism to create new, highly skilled Australian industries.Read moreRead less
Complex Dopant Diffusivity in Photonic Crystal Fibres and Applications. The outcomes of this research in the area of doped photonic crystal fibres will enable Australia to commercialise the technology and provide an opportunity for leading commercial ventures using novel doped PCF. These opportunities will eventually become large-scale industrial activities developed from the research in fields such as sensing, biophotonics, medical and defence and will result in significant economic benefit for ....Complex Dopant Diffusivity in Photonic Crystal Fibres and Applications. The outcomes of this research in the area of doped photonic crystal fibres will enable Australia to commercialise the technology and provide an opportunity for leading commercial ventures using novel doped PCF. These opportunities will eventually become large-scale industrial activities developed from the research in fields such as sensing, biophotonics, medical and defence and will result in significant economic benefit for Australia. Fundamental research outcomes in glass and dopants that can boost devices and introduce novel devices resulting from this project will contribute to all National Research Priorities.Read moreRead less
Novel High-Q Resonant Structures for Space and Telecommunications. High-Q microwave resonators with low spurious mode density have important applications in telecommunications, radar, navigation, precision metrology and time standards. We will develop high-Q resonators by constructing a dielectric Bragg resonators using monocrystalline sapphire loaded in a copper cavity with new cylindrical and spherical geometries. Based on these devices, compact and economical state-of-the-art ultra-low noise ....Novel High-Q Resonant Structures for Space and Telecommunications. High-Q microwave resonators with low spurious mode density have important applications in telecommunications, radar, navigation, precision metrology and time standards. We will develop high-Q resonators by constructing a dielectric Bragg resonators using monocrystalline sapphire loaded in a copper cavity with new cylindrical and spherical geometries. Based on these devices, compact and economical state-of-the-art ultra-low noise microwave oscillators and hydrogen masers will be built for the telecommunications market and space applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560710
Funder
Australian Research Council
Funding Amount
$242,000.00
Summary
A Facility for Ultra-Precise Time and Frequency Transfer: Creating an Australian User Group for the ESA Atomic Clock Ensemble in Space Mission. The National Measurement Laboratory and the University of Western Australia are the only Australian research institutions developing high precision electromagnetic oscillators ("clocks"). Establishing the state-of-the-art time transfer link between these institutions will combine their expertise and allow a broad spectrum of new research activities impor ....A Facility for Ultra-Precise Time and Frequency Transfer: Creating an Australian User Group for the ESA Atomic Clock Ensemble in Space Mission. The National Measurement Laboratory and the University of Western Australia are the only Australian research institutions developing high precision electromagnetic oscillators ("clocks"). Establishing the state-of-the-art time transfer link between these institutions will combine their expertise and allow a broad spectrum of new research activities important for frequency metrology, global positioning and accurate tests of fundamental physics. The time transfer facility will also create the infrastructure necessary for Australia participation in the future international space mission - Atomic Clock Ensemble in Space.Read moreRead less
Nano-Engineering of Optical Fibre Fresnel Lenses. It is expected that the development of the Fresnel Lens Fibre will greatly enhance the simplicity with which fibres can be integrated into a variety of systems. An intrinsically focussing fibre will be cheap to produce and have significant size advantages over its competitors, thus giving it an excellent competitive advantage in the market place. Australia is home to a number of companies that would directly benefit from the commercialisation of ....Nano-Engineering of Optical Fibre Fresnel Lenses. It is expected that the development of the Fresnel Lens Fibre will greatly enhance the simplicity with which fibres can be integrated into a variety of systems. An intrinsically focussing fibre will be cheap to produce and have significant size advantages over its competitors, thus giving it an excellent competitive advantage in the market place. Australia is home to a number of companies that would directly benefit from the commercialisation of a Fresnel Lens Fibre. In addition to a range of possible telecommunications applications, the focussing fibre also has applications in spectroscopy, minimally invasive surgical procedures, and especially in the field of photodynamic therapy. Read moreRead less
Fractal Based Index Profiles for a New Class of Optical Fibre. Australia has a strong base in photonics serving technological advanced areas of perimeter security, minimally invasive surgical applications, high resolution imaging and optical sensing . Our photonic companies need novel fibre optic advances to stay competitive internationally in order to open new marketing opportunities being driven by market pull. The present innovation will add single fibre solution, fractal based technology, an ....Fractal Based Index Profiles for a New Class of Optical Fibre. Australia has a strong base in photonics serving technological advanced areas of perimeter security, minimally invasive surgical applications, high resolution imaging and optical sensing . Our photonic companies need novel fibre optic advances to stay competitive internationally in order to open new marketing opportunities being driven by market pull. The present innovation will add single fibre solution, fractal based technology, an Australian scientific advance, to the range of technologies supporting our advanced materials-photonic companies.Read moreRead less
Special Research Initiatives - Grant ID: SR0567321
Funder
Australian Research Council
Funding Amount
$184,781.00
Summary
Real-time Very Long Baseline Interferometry. We will develop a range of software products that are required to implement real-time very long baseline interferometry with the Australia long baseline array. These developments build upon substancial recent infrastructure investments and will place Australia at the forefront of this field. They will enhance our capacity to participate in international collaborations in a range of sciences including astrophysics, spacecraft tracking and geodetic mo ....Real-time Very Long Baseline Interferometry. We will develop a range of software products that are required to implement real-time very long baseline interferometry with the Australia long baseline array. These developments build upon substancial recent infrastructure investments and will place Australia at the forefront of this field. They will enhance our capacity to participate in international collaborations in a range of sciences including astrophysics, spacecraft tracking and geodetic monitoring.Read moreRead less
Frequency stabilisation in the Extremely High Frequency band. All precision communication and measurement systems (i.e. radar and navigation) rely on high quality oscillator technology. Any improvement in oscillator performance has a direct impact on the performance of the system and hence is of potential economic benefit. This project will realise the most stable frequencies ever produced in the underused Extremely High Frequency band, which is also important for space communications and naviga ....Frequency stabilisation in the Extremely High Frequency band. All precision communication and measurement systems (i.e. radar and navigation) rely on high quality oscillator technology. Any improvement in oscillator performance has a direct impact on the performance of the system and hence is of potential economic benefit. This project will realise the most stable frequencies ever produced in the underused Extremely High Frequency band, which is also important for space communications and navigation technology. System enhancement will include, better angular resolution, higher bandwidths, faster transmission rates and narrower beam widths without the susceptibility of absorption apparent from the optical domain.Read moreRead less