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
Reconfigurable MicroPhotonic Processor. This research aims to study a new reconfigurable MicroPhotonic processor capable of performing many optical functions simultaneously. In this project, research is particularly focused on reconfigurable optical add/drop multiplexing (ROADM) for future Dense Wavelength Division Multiplexed (DWDM) optical networks. The significance of the MicroPhotonic architecture is that it can add/drop a single or multiple wavelength channels, and can scale to tens of chan ....Reconfigurable MicroPhotonic Processor. This research aims to study a new reconfigurable MicroPhotonic processor capable of performing many optical functions simultaneously. In this project, research is particularly focused on reconfigurable optical add/drop multiplexing (ROADM) for future Dense Wavelength Division Multiplexed (DWDM) optical networks. The significance of the MicroPhotonic architecture is that it can add/drop a single or multiple wavelength channels, and can scale to tens of channels while maintaining low insertion loss and low crosstalk. The outcome will be a new reconfigurable MicroPhotonic ROADM architecture which overcomes existing scaling bottlenecks for processing hundreds of DWDM channels.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347464
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Setting up an integrated wirebonding and testing facility for MEMS applications. This project intends to setup an integrated wire bonding and testing facility suitable for Micro electromechanical systems (MEMS) applications. Wire bonding is an essential step for making the contacts of any micro device with external power supply or signal conditioning circuitry. The contact pads for such devices vary in size from 0.050 mm x 0.050 mm to few 100s of micrometers. The proposed facility will be requi ....Setting up an integrated wirebonding and testing facility for MEMS applications. This project intends to setup an integrated wire bonding and testing facility suitable for Micro electromechanical systems (MEMS) applications. Wire bonding is an essential step for making the contacts of any micro device with external power supply or signal conditioning circuitry. The contact pads for such devices vary in size from 0.050 mm x 0.050 mm to few 100s of micrometers. The proposed facility will be required for making contacts either using thermal or ultrasonic methods with complete automatic stages. The electrical contacts are used to drive or monitor MEMS, Polymer micro devices and nano- fluidic systems. This facility will be used for different applications including photonics and communication devices (RMIT), flexi circuits and microwave devices (DSTO) and micro/nano fluidic systems (SUT). This will be the only advanced integrated facility in Victoria, which will have the wire bonding(ball & wedge), die bonding and bond testing facilities together.Read moreRead less
Novel silicon photonic devices harnessing new leakage behaviour. The continuing advance of microprocessor performance requires vast quantities of data to be transferred between on-chip processor cores and to the outside world. The transfer of data via metal wires cannot meet this demand due to limited bandwidth and astonishing heat generation. Low-loss photonic transport integrated onto the silicon chip offers a solution. With this project we will explore harnessing a newly discovered phenomenon ....Novel silicon photonic devices harnessing new leakage behaviour. The continuing advance of microprocessor performance requires vast quantities of data to be transferred between on-chip processor cores and to the outside world. The transfer of data via metal wires cannot meet this demand due to limited bandwidth and astonishing heat generation. Low-loss photonic transport integrated onto the silicon chip offers a solution. With this project we will explore harnessing a newly discovered phenomenon in silicon photonics to achieve devices such as electrically pumped lasers and wavelength routers. The project will collaborate closely with researchers in the USA, but will focus on research of designs that can be created in Australia and licensed to major industry across the globe.
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Probe based nano-fabrication of micro-electronic and mechanical systems. Integrated circuits (ICs) are the ubiquitous core of today's computers, medical devices and mobile phones. Unfortunately, advanced ICs are becoming more costly and difficult to fabricate. This project proposes a new method that uses a tiny, intense spot of light to create low-cost ICs that are small, fast and will enable a vast range of new technologies.
Extending the lifetime of switching power converters. This project aims to address the need for longer lifespan of power conversion systems which can withstand failure of its key components. This is achieved through developing more reliable power converter circuits whilst reducing the stress of the components. This project will generate new circuit design and control techniques for power and energy systems, especially in dealing with reliability issues. Expected outcome of this project includes ....Extending the lifetime of switching power converters. This project aims to address the need for longer lifespan of power conversion systems which can withstand failure of its key components. This is achieved through developing more reliable power converter circuits whilst reducing the stress of the components. This project will generate new circuit design and control techniques for power and energy systems, especially in dealing with reliability issues. Expected outcome of this project includes reduction of failure rate of power converters by at least 50%. This should provide benefits for many sectors including emerging technologies in particular renewable energy, electric vehicles and energy storage systems seeking reliable power supply and for the environment with reduced e-waste production.Read moreRead less
Optimum location of FACTS devices with advanced control scheme for improving the security of complex power grid. Prevention of blackouts is one of the highest priorities of the electricity industry. One of the fundamental reasons for the recent blackouts in long transmission network is inter-area oscillations. Queensland's long transmission network is a vital part of the Australian electricity grid and is vulnerable to inter-area oscillations. There is a need for a comprehensive approach to inve ....Optimum location of FACTS devices with advanced control scheme for improving the security of complex power grid. Prevention of blackouts is one of the highest priorities of the electricity industry. One of the fundamental reasons for the recent blackouts in long transmission network is inter-area oscillations. Queensland's long transmission network is a vital part of the Australian electricity grid and is vulnerable to inter-area oscillations. There is a need for a comprehensive approach to investigate the effect of inter-area oscillation that contributes to blackouts. Focussing the Queensland network, this project will provide a complete assessment tool for the optimum location of FACTS devices with modern and advanced control schemes in improving the security of complex interconnected power-grid. Read moreRead less
Tunable metamaterials for terahertz and infrared applications. This project proposes novel low-cost miniature devices for spectroscopic, spatial, and temporal manipulation of infrared and terahertz waves, which are important for security and short range communication applications. By enabling the modulation of infrared and terahertz signals, the intended outcome is a platform for imaging applications, detection of chemical composition of objects, and future high-bandwidth communications. Using m ....Tunable metamaterials for terahertz and infrared applications. This project proposes novel low-cost miniature devices for spectroscopic, spatial, and temporal manipulation of infrared and terahertz waves, which are important for security and short range communication applications. By enabling the modulation of infrared and terahertz signals, the intended outcome is a platform for imaging applications, detection of chemical composition of objects, and future high-bandwidth communications. Using microfabrication techniques, the project plans to create metamaterials integrated with micro-electro-mechanical systems, which dynamically vary their electromagnetic properties. This technology would enable the creation of new devices that can controllably absorb, reflect or transmit infrared and terahertz signals.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101118
Funder
Australian Research Council
Funding Amount
$314,446.00
Summary
Enabling high photovoltaic penetration in power distribution networks. This project aims to develop a novel hybrid control method for power distribution grid network voltage regulation with high photovoltaic penetration. The outcome of this project will enable power utilities to cost-effectively regulate network voltage and ultimately remove barriers for future photovoltaic deployment. This will deliver significant economic benefits for both the wider community and utility providers, along with ....Enabling high photovoltaic penetration in power distribution networks. This project aims to develop a novel hybrid control method for power distribution grid network voltage regulation with high photovoltaic penetration. The outcome of this project will enable power utilities to cost-effectively regulate network voltage and ultimately remove barriers for future photovoltaic deployment. This will deliver significant economic benefits for both the wider community and utility providers, along with substantial environmental outcomes through increased use of sustainable energy sources.Read moreRead less
Smart house energy management system. This multidisciplinary project will empower Australia's power industry with tools and knowledge that will enable the transformation to be more intelligent and flexible. It will help reduce greenhouse gas emissions and increase energy efficiency by smarter use of the resources at household level.