Exploring Synergies between Frontier Microphotonics and Advanced Time and Frequency Technology. Recently scientists have developed the means to manufacture objects that are on the same microscopic scale as light itself. These structures can deliver exquisite control of the properties of the light beams. Our existing research has been aimed at developing some of the world's most precise measurement tools based on clocks and the pure colours generated by lasers. By combining these two technologie ....Exploring Synergies between Frontier Microphotonics and Advanced Time and Frequency Technology. Recently scientists have developed the means to manufacture objects that are on the same microscopic scale as light itself. These structures can deliver exquisite control of the properties of the light beams. Our existing research has been aimed at developing some of the world's most precise measurement tools based on clocks and the pure colours generated by lasers. By combining these two technologies, both of which lie at the extreme limit of precision, we will develop a new generation of technology for fundamental science objectives as well as for industrial needs.Read moreRead less
Spectral analysis with selective harmonic emphasis. This project lies under ARC research priority area "Frontier Technologies for Building and Transforming Australian Industries". The signal processing algorithms to be developed in this project will be useful in many important practical applications, which include various bio-medical imaging modalities, beamforming, radar, sonar and target tracking using sensor arrays. The idea is to use the prior knowledge to enhance certain desired properties ....Spectral analysis with selective harmonic emphasis. This project lies under ARC research priority area "Frontier Technologies for Building and Transforming Australian Industries". The signal processing algorithms to be developed in this project will be useful in many important practical applications, which include various bio-medical imaging modalities, beamforming, radar, sonar and target tracking using sensor arrays. The idea is to use the prior knowledge to enhance certain desired properties of the algorithms via intelligent processing. In this light the project also lies within the ARC research priority area of "Smart Information use".Read moreRead less
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: LE0221428
Funder
Australian Research Council
Funding Amount
$530,000.00
Summary
A Transportable Optical Frequency Counter, Synthesizer and Super-Continuum Generator (OFCSSG). The generation of ultra-short light pulses of just a few femtoseconds (one thousand-trillionth of a second) in duration has enabled applications in a wide range of fields, but complexity and cost has limited availability. This project will employ recently developed optical fibre and solid-state laser technology to create a cost-effective compact transportable facility of highly coherent, ultra-broadba ....A Transportable Optical Frequency Counter, Synthesizer and Super-Continuum Generator (OFCSSG). The generation of ultra-short light pulses of just a few femtoseconds (one thousand-trillionth of a second) in duration has enabled applications in a wide range of fields, but complexity and cost has limited availability. This project will employ recently developed optical fibre and solid-state laser technology to create a cost-effective compact transportable facility of highly coherent, ultra-broadband radiation. The source will enable new research and substantially enrich existing research in optical time standards and metrology, in-vivo biological imaging, and ultrafast spectroscopy. No such facility is presently available in AustraliaRead moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347462
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Femtosecond laser micromachining facility. The proposed establishment of a femtosecond laser micromachining facility, with microdiagnostic capabilities, will facilitate a range of projects involving fabrication of submicron structures in metals, polymers, glasses, ceramics and crystalline materials. This facility, unique in Australia , will be comparable to the best such facilities in the world, enabling researchers to apply new microfabrication techniques to a range of photonic and optoelectro ....Femtosecond laser micromachining facility. The proposed establishment of a femtosecond laser micromachining facility, with microdiagnostic capabilities, will facilitate a range of projects involving fabrication of submicron structures in metals, polymers, glasses, ceramics and crystalline materials. This facility, unique in Australia , will be comparable to the best such facilities in the world, enabling researchers to apply new microfabrication techniques to a range of photonic and optoelectronic devices, including laser-written optical planar waveguides, nonlinear components and photonic bandgap structures , and various biomedical microstructures. Outcomes will include demonstration and development of novel photonic/optoelectronic devices and of new techniques, crucial to cost-effective manufacture of photonic components.Read moreRead less
System Theoretical Aspects of Spatial Signal Processing. The aims of the project is to gain better understanding of spatial characteristics of wireless communication channels; and to apply spatial signal processing theory to design receivers for wireless systems. The expected outcomes of the projects are new system theory for spatial signal processing, a new spatial model to characterize wireless communication channels, categorize a relationship between scattering environment antenna spacing and ....System Theoretical Aspects of Spatial Signal Processing. The aims of the project is to gain better understanding of spatial characteristics of wireless communication channels; and to apply spatial signal processing theory to design receivers for wireless systems. The expected outcomes of the projects are new system theory for spatial signal processing, a new spatial model to characterize wireless communication channels, categorize a relationship between scattering environment antenna spacing and multi-element antenna system capacity, and novel use of multiple antennas to improve the performance of wireless systems. Success in this investigation could have wide applications in the development of future mobile and fixed wireless communication systems.Read moreRead less
Overcoming Transistor Performance Issues for Emerging Millimetre-Wave Applications. The operation of transistors for emerging millimeter-wave applications, such as point to point communications and automotive radar, will be researched. The aim is to develop circuit design methodologies that extract better performance from a given fabrication process, thus giving a competitive advantage to local industry, which shares the process with other international companies. Transistor operating range, lin ....Overcoming Transistor Performance Issues for Emerging Millimetre-Wave Applications. The operation of transistors for emerging millimeter-wave applications, such as point to point communications and automotive radar, will be researched. The aim is to develop circuit design methodologies that extract better performance from a given fabrication process, thus giving a competitive advantage to local industry, which shares the process with other international companies. Transistor operating range, linearity and characterisation will be enhanced. New models and demonstrator circuits will be produced. The project will skill postgraduates in microwave theory and techniques applied to the development of high performance circuits.Read moreRead less
High-Performance Microwave and Millimetre Wave Antennae Based on Multi-layer Periodic Structures. Broadband communication has created a rapidly growing market for innovative microwave communication systems such as WiFi and WiMAX. Millimetre-wave technology is expected to deliver the next leap in communication technology with much faster wireless links for 3D TV etc. By developing innovative, low-cost, planar antennas with high performance, the proposed research will create opportunities for Aust ....High-Performance Microwave and Millimetre Wave Antennae Based on Multi-layer Periodic Structures. Broadband communication has created a rapidly growing market for innovative microwave communication systems such as WiFi and WiMAX. Millimetre-wave technology is expected to deliver the next leap in communication technology with much faster wireless links for 3D TV etc. By developing innovative, low-cost, planar antennas with high performance, the proposed research will create opportunities for Australian industry to compete in this growing global market with advanced, cost-effective, microwave and millimetre-wave products. The Australian research community will benefit from new methods, techniques and trained researchers, while Australian consumers will benefit from improved quality and low cost of services.Read moreRead less
Hybrid-resonator antennas for wireless communication networks. The rapid emergence of modern wireless communication systems has led to a requirement for small, lightweight antennas. In this project, a new, broadband, low-cost, small and lightweight antenna architecture will be developed for wireless systems. The new architecture is based on a novel hybrid-resonator concept: a dielectric resonator tightly coupled to a metal patch resonator. The rapid design and optimisation of new antennas will b ....Hybrid-resonator antennas for wireless communication networks. The rapid emergence of modern wireless communication systems has led to a requirement for small, lightweight antennas. In this project, a new, broadband, low-cost, small and lightweight antenna architecture will be developed for wireless systems. The new architecture is based on a novel hybrid-resonator concept: a dielectric resonator tightly coupled to a metal patch resonator. The rapid design and optimisation of new antennas will be achieved by developing several new theoretical methods. Antennas targeted for the Unlicensed National Information Infrastructure (UNII) band (5-6 GHz) commercial wireless communication systems will be designed, fabricated, tested and integrated with the systems.
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