Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100061
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
FlashLite: A High Performance Machine for Data Intensive Science. FlashLite: a high performance machine for data intensive science: The 21st century has been described as the century of data. Experts predict an exponential growth in the amount of data that will be captured, generated and archived. Australia has made significant progress towards addressing some of the opportunities and infrastructure challenges posed by such rapid increase in data volumes. However, these investments do not addre ....FlashLite: A High Performance Machine for Data Intensive Science. FlashLite: a high performance machine for data intensive science: The 21st century has been described as the century of data. Experts predict an exponential growth in the amount of data that will be captured, generated and archived. Australia has made significant progress towards addressing some of the opportunities and infrastructure challenges posed by such rapid increase in data volumes. However, these investments do not address the growing need to process data. Conventional supercomputers are unable to meet the challenges of the data explosion. The large gap in latency and bandwidth between the processor, memory and disk subsystems means that the processor is often idle waiting to fetch data. This project will build a platform focussed on data intensive science.Read moreRead less
Towards a high density silicon phase change memory device. This project builds upon our exciting recent findings that amorphous silicon can be transformed to a conducting crystalline phase following small-scale indentation. Furthermore the process is reversible as re-indentation can induce a transformation back to insulating amorphous silicon. This process appears to occur in extremely small (nanoscale) volumes of silicon. We plan to explore the viability of exploiting this behaviour to develo ....Towards a high density silicon phase change memory device. This project builds upon our exciting recent findings that amorphous silicon can be transformed to a conducting crystalline phase following small-scale indentation. Furthermore the process is reversible as re-indentation can induce a transformation back to insulating amorphous silicon. This process appears to occur in extremely small (nanoscale) volumes of silicon. We plan to explore the viability of exploiting this behaviour to develop an entirely new information storage system: a high-density silicon phase change memory. This project aims to study small-scale transformation behaviour in silicon and to design demonstrator memory devices based on both micro-electromechanical systems and solid state technologies.Read moreRead less
Low power memory for modern embedded systems. This project will create methods and circuits to reduce power consumption of embedded systems through memory optimisations. Power efficient embedded systems, will enable smaller, more portable systems and reduce battery usage by 2.5 per cent (worth over US$1.8 billion dollars) and lower toxic waste levels (e.g., heavy metals such as mercury, cadmium etc.).
Monitoring and Control of Complex Power Systems via Robust Control of Jump Parameter Systems. The project will involve research on a robust state estimation and control theory of systems with uncertain and random structure. This theory will be applied to develop new tools for dynamic voltage stability analysis and control of complex power systems by taking into account discrete switching of devices comprising the system. The theory will address both performance and robustness of power systems ag ....Monitoring and Control of Complex Power Systems via Robust Control of Jump Parameter Systems. The project will involve research on a robust state estimation and control theory of systems with uncertain and random structure. This theory will be applied to develop new tools for dynamic voltage stability analysis and control of complex power systems by taking into account discrete switching of devices comprising the system. The theory will address both performance and robustness of power systems against variety of uncertainties including those due to modelling errors associated with uncertain nature of discrete switching and nonlinearity of underlying power generation system models.Read moreRead less
Analysis and Design of Networked Control Systems. Rapid advances in communications technology have opened up the possibility of large scale control systems in which the control task is distributed among several processors and the communication between the processors, sensors and actuators is via communication channels. This enables control systems to be distributed over large distances and to use large numbers of actuators and sensors. This project will be directed towards the development of a t ....Analysis and Design of Networked Control Systems. Rapid advances in communications technology have opened up the possibility of large scale control systems in which the control task is distributed among several processors and the communication between the processors, sensors and actuators is via communication channels. This enables control systems to be distributed over large distances and to use large numbers of actuators and sensors. This project will be directed towards the development of a theory of networked control systems in which control and communication issues are combined together, and all the limitations of the communication channels are taken into account.Read moreRead less
Provably Correct on-chip Communication-based Design. This project falls in the priority area of Frontier Technologies for Building and Transforming Australian Industries. Embedded systems have complex communication architectures and functionalities due to their mission- and time-critical applications. This project will develop verifiable algorithms and techniques for design reuse to address them, help solve outstanding problems in the VLSI/SoC community and to lift the country's visibility and ....Provably Correct on-chip Communication-based Design. This project falls in the priority area of Frontier Technologies for Building and Transforming Australian Industries. Embedded systems have complex communication architectures and functionalities due to their mission- and time-critical applications. This project will develop verifiable algorithms and techniques for design reuse to address them, help solve outstanding problems in the VLSI/SoC community and to lift the country's visibility and credibility in the area. The economic benefits are better techniques for design reuse for embedded systems that may be integrated into existing Computer Aided Design environments, with potential to commercialise the algorithms to Electronic Design Automation and vendors.Read moreRead less
Development of advanced metal oxide materials for next generation nonvolatile memory devices. The purpose of the project is to explore a new memory technology, resistive random-access memory, that can be made smaller than those of today, as well as preferably being faster, power saving and nonvolatile. The project is expected to bring resistive random-access memory materials a step closer to nonvolatile memory devices application.
Uncertain Systems Theory applied to Nonlinear Robust Control and Filtering. Feedback control systems are becoming increasingly important in manufacturing industry, the automotive industry, defence applications as well as in many non-industrial applications such as the management of the environment or the economy. By developing new techniques for the design of high performance robust nonlinear controllers and filters which are widely applicable in industrial applications, this project will help m ....Uncertain Systems Theory applied to Nonlinear Robust Control and Filtering. Feedback control systems are becoming increasingly important in manufacturing industry, the automotive industry, defence applications as well as in many non-industrial applications such as the management of the environment or the economy. By developing new techniques for the design of high performance robust nonlinear controllers and filters which are widely applicable in industrial applications, this project will help make existing industrial technologies more efficient and make new industrial technologies feasible. Moreover, the research training carried out in the project will add to available a pool of experts in the areas of robust nonlinear control and filtering. Read moreRead less
Design Automation for Processor Pipelines. Embedded system processors comprise about eighty percent of the processor market. This project targets this particular segment, customising multi-processor system on chips for a particular class of embedded applications, resulting in superior performance, low power and reduced cost. Direct benefits will include clear understanding of architectures and algorithms, research training, better processors for the embedded market, and quality publications. Ind ....Design Automation for Processor Pipelines. Embedded system processors comprise about eighty percent of the processor market. This project targets this particular segment, customising multi-processor system on chips for a particular class of embedded applications, resulting in superior performance, low power and reduced cost. Direct benefits will include clear understanding of architectures and algorithms, research training, better processors for the embedded market, and quality publications. Indirect benefits will be commercialisation and licensing of this technology for use in the embedded systems design industry. Companies which can benefit from this technology exist in Australia and overseas.Read moreRead less
Mapping electronic structure and material properties with atomic resolution. This project will use electron energy loss spectroscopy (EELS) to map the bonding and electronic structure of InGaN quantum wells at the atomic scale. We will measure and correlate the local composition, strain and electronic structure variations within the wells in order to understand the optical emission in this system. The characterisation tools developed will allow us to go beyond measuring structure and composition ....Mapping electronic structure and material properties with atomic resolution. This project will use electron energy loss spectroscopy (EELS) to map the bonding and electronic structure of InGaN quantum wells at the atomic scale. We will measure and correlate the local composition, strain and electronic structure variations within the wells in order to understand the optical emission in this system. The characterisation tools developed will allow us to go beyond measuring structure and composition and map properties of nano-materials at the atomic scale.Read moreRead less