Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100205
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A novel high-pressure system for multiple gas adsorption. This facility will equip researchers with analytical capabilities for research in the field of multi-gas adsorption. The facility will be of great significance to clean energy research, such as greenhouse gas emission control and hydrogen production and storage.
Structural modelling of silicon carbide-derived microporous carbon and its application in carbon dioxide capture from moist gases. The project will deliver a powerful new tool for determining the nanostructure of carbons, and will advance the modelling of fluid equilibrium, accessibility and transport within this structure. The outcomes will be crucial to the development of emerging technologies in nanofluidics, gas and electrochemical energy storage, and gas separation.
Mechanisms and innovative technologies for machining nanoscale multilayered thin film solar panels. This project addresses an important manufacturing bottleneck in the solar energy industry by addressing significant limitations in machining multilayered solar panels. A successful outcome will provide an important breakthrough in machining technology applicable not only to solar panels but other material science applications.
Multivariate Methods for the Analysis of Microarray Gene-Expression Data with Applications to Cancer Diagnostics. The project will benefit the Australian Society as a whole by developing statistical methodology for the analysis of high-throughput data. In particular, it will develop a novel and easily implemented model for the analysis of correlated and structured data that may be of high dimension. It thus has wide applicability to improving the quality and validity of applied research in most ....Multivariate Methods for the Analysis of Microarray Gene-Expression Data with Applications to Cancer Diagnostics. The project will benefit the Australian Society as a whole by developing statistical methodology for the analysis of high-throughput data. In particular, it will develop a novel and easily implemented model for the analysis of correlated and structured data that may be of high dimension. It thus has wide applicability to improving the quality and validity of applied research in most industries in Australia. More specifically, it is to be applied here to the diagnosis and prognosis of ovarian cancer. This cross-disciplinary project will strengthen Australian researchers' capacity and capability of participating in cutting-edge DNA microarray research.
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Discovery Early Career Researcher Award - Grant ID: DE130101183
Funder
Australian Research Council
Funding Amount
$361,880.00
Summary
Next-generation expanders for renewable power applications: dealing with variability and uncertainty. This project will develop new strategies to design optimum expanders capable of maintaining good performance under uncontrollable working conditions. If these innovative design methods can be applied to engineering applications they will assist Australia to meet the Renewable Energy Target and to become an international leader in the field.
Enhanced Multilingual Speaker Recognition through the Incorporation of High-Level Features, Late Fusion and Discriminative Classification Methods. The development of robust multilingual speaker recognition systems will benefit the community through the elimination of fraud incurred by financial institutions and customers by enabling several person authentication applications such as: voice based signatures and document issuance; credit card verification by voice and secure over-the-phone financi ....Enhanced Multilingual Speaker Recognition through the Incorporation of High-Level Features, Late Fusion and Discriminative Classification Methods. The development of robust multilingual speaker recognition systems will benefit the community through the elimination of fraud incurred by financial institutions and customers by enabling several person authentication applications such as: voice based signatures and document issuance; credit card verification by voice and secure over-the-phone financial transactions. The technology will also assist in the protection of the community and safeguard Australia by enabling the implementation of the following: suspect identification using voice print; national security measures for combating terrorism by using voice to locate and track terrorists; preemptive criminal activity counter-measures; surveillance and secure building access by voice.Read moreRead less
Robust speaker recognition with reduced utterance duration and intersession variability. The development of robust and accurate speaker recognition systems will enable secure person authentication in over-the-phone financial transactions and benefit the community through the elimination of identity fraud incurred by customers and financial institutions. The technology will also assist in safeguarding Australia by enabling the implementation of suspect identification using voice and security meas ....Robust speaker recognition with reduced utterance duration and intersession variability. The development of robust and accurate speaker recognition systems will enable secure person authentication in over-the-phone financial transactions and benefit the community through the elimination of identity fraud incurred by customers and financial institutions. The technology will also assist in safeguarding Australia by enabling the implementation of suspect identification using voice and security measures for combating terrorism by using voice to locate and track terrorists. Our research at QUT Speech Research Lab is at the forefront of development in this field and will provide Australia with a technological advantage in the rapidly evolving global market for speaker recognition technology for person authentication applications.Read moreRead less
Robust Automatic Speaker Diarisation of Audio Documents by Exploiting Prior Sources of Information. Speaker Diarisation, the task of determining who spoke when, is a technology fundamental in deriving intelligent information from audio and multimedia resources. The requirement for efficient and accurate Speaker Diarisation systems, portable across different domains is heightened by the explosive growth of audio and multimedia archives online and throughout the world. This research will provide t ....Robust Automatic Speaker Diarisation of Audio Documents by Exploiting Prior Sources of Information. Speaker Diarisation, the task of determining who spoke when, is a technology fundamental in deriving intelligent information from audio and multimedia resources. The requirement for efficient and accurate Speaker Diarisation systems, portable across different domains is heightened by the explosive growth of audio and multimedia archives online and throughout the world. This research will provide the foundation for a commercial service of automatic Speaker Diarisation to be developed, growing Australia's impact on the information and communications technology (ICT) sector. The outcome of this research will also assist in the tracking of terrorist and unlawful activity by enabling effective intelligence gathering from different audio sources.Read moreRead less
Improved design and operational efficiency of small wind turbines in unsteady flows. The purpose of this research is to improve the design and performance of small wind turbines for energy generation. The expected outcomes are novel control strategies and mechanical designs that account for unsteady aerodynamics and its effects on structural loads and power quality. Recommendations to improve current design standards will be made.
Design of Functionalized Mesoporous Fullerenes for Clean Energy. This project aims to design multifunctional, noble metal-free, and highly ordered mesoporous fullerene with a high conductivity and different porous structures, functionalised with nitrogen and/or metal and metal oxide nanoparticles in both powder and film forms. The most promising, stable, and highly efficient noble metal-free electrode catalyst system will be designed with the functionalised mesoporous fullerenes for polymer elec ....Design of Functionalized Mesoporous Fullerenes for Clean Energy. This project aims to design multifunctional, noble metal-free, and highly ordered mesoporous fullerene with a high conductivity and different porous structures, functionalised with nitrogen and/or metal and metal oxide nanoparticles in both powder and film forms. The most promising, stable, and highly efficient noble metal-free electrode catalyst system will be designed with the functionalised mesoporous fullerenes for polymer electrolyte membrane and direct methanol fuel cells. This novel highly efficient and low cost electrode system for fuel cells aims to help address clean energy generation and environmental problems and create new opportunities for Australian industries.Read moreRead less