Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100126
Funder
Australian Research Council
Funding Amount
$527,638.00
Summary
Advanced Maskless Photolitography for Western Australia. This project aims to close an existing gap in micro- & nano-fabrication in Western Australia and provide access to advanced maskless photolithography in support of Australian research flagships of international excellence which include advanced infrared and quantum technologies, semiconductor optoelectronics, chemical engineering, microelectromechanical systems, as well as dark matter and gravitational wave discovery. Notably, the new capa ....Advanced Maskless Photolitography for Western Australia. This project aims to close an existing gap in micro- & nano-fabrication in Western Australia and provide access to advanced maskless photolithography in support of Australian research flagships of international excellence which include advanced infrared and quantum technologies, semiconductor optoelectronics, chemical engineering, microelectromechanical systems, as well as dark matter and gravitational wave discovery. Notably, the new capability is of utmost importance for five distinct ARC Centres in multidisciplinary areas and will be available to all researchers via the WA Node of Australian National Fabrication Facility in support of high impact scientific research and to maintain strong engagement with industry and Australian economy.Read moreRead less
Reliable Truly Deep Sub-micron VLSI Computational Systems. The phenomenal growth of the digital integrated circuits is founded on the fundamental assumption of reliable operation of logic gates on silicon chip. In the Deep Sub-Micron domain this fundamental assumption can no longer be guaranteed. This project, in association with with Dongshin University, Korea with strong links to the semiconductor industry, will develop design techniques for the reliable computational hardware, in the presence ....Reliable Truly Deep Sub-micron VLSI Computational Systems. The phenomenal growth of the digital integrated circuits is founded on the fundamental assumption of reliable operation of logic gates on silicon chip. In the Deep Sub-Micron domain this fundamental assumption can no longer be guaranteed. This project, in association with with Dongshin University, Korea with strong links to the semiconductor industry, will develop design techniques for the reliable computational hardware, in the presence of unreliable circuit fabric. This significant research, with potential for generation of IP, will raise the profile of Australian research in integrated circuits design in the global community and will result in significant publicity for the research team and, through them, for Australian industry.Read moreRead less
MEMS Based Chip-to-Chip Optical Interconnect for Future Generation of Systems In a Package. The project will bring Australian technical known-how into the forefront of the information and communication technology revolution. The technology developed in this project will enable computers to operate at very high speeds. More information can be communicated than ever before. This has significant impact on Australian society where speed of information is increasingly important. The technical knowl ....MEMS Based Chip-to-Chip Optical Interconnect for Future Generation of Systems In a Package. The project will bring Australian technical known-how into the forefront of the information and communication technology revolution. The technology developed in this project will enable computers to operate at very high speeds. More information can be communicated than ever before. This has significant impact on Australian society where speed of information is increasingly important. The technical knowledge of how to make computers operate faster has great commercial value and would be very much sought after. Hence, its impact on the national economy. Read moreRead less
Design Methodology for Low- and Ultra-Low Power Integrated Circuits. This project will develop low-power and ultra low-power technology that is applicable to wide range of products and electronic devices. The results will benefit many areas, for example, wireless sensors employed in environmental monitoring, bio and life monitoring, bio-sensors to improve patient care, reduce medical costs, implantable devices and bio-interfaces that will enhance the quality of life and public health. This proje ....Design Methodology for Low- and Ultra-Low Power Integrated Circuits. This project will develop low-power and ultra low-power technology that is applicable to wide range of products and electronic devices. The results will benefit many areas, for example, wireless sensors employed in environmental monitoring, bio and life monitoring, bio-sensors to improve patient care, reduce medical costs, implantable devices and bio-interfaces that will enhance the quality of life and public health. This project will benefit Australia by developing frontier technologies with a strong potential for global impact. Bringing these solutions to the public and realizing their financial benefits will add a valuable component of economic diversity to the country in addition to positioning Australia as a leader in this field.Read moreRead less
Low Power Architectures for the Wavelet Transform and JPEG2000. Recently a new international standard for image compression has been proposed, JPEG2000. This new method updates the well established JPEG standard and will be incorporated into digital cameras, web pads, etc.
In this project we will investigate low power architectures for the wavelet transforms used in this standard, and combine this with an embedded processor core to deliver a complete system on a chip solution for low power JPEG ....Low Power Architectures for the Wavelet Transform and JPEG2000. Recently a new international standard for image compression has been proposed, JPEG2000. This new method updates the well established JPEG standard and will be incorporated into digital cameras, web pads, etc.
In this project we will investigate low power architectures for the wavelet transforms used in this standard, and combine this with an embedded processor core to deliver a complete system on a chip solution for low power JPEG2000.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0345794
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Spectroscopic Imaging Ellipsometry for Opto-VLSI Engineering and Nanotechnology Applications. The focus for implementation of spectroscopic imaging ellipsometry is to create a powerful optical analysis and characterisation tool to complement the advanced integrated circuit test facilities within Western Australia. This infrastructure will facilitate the integration of the fields of materials research, new device technologies, integrated circuit technology, nanotechnology and photonics in the exp ....Spectroscopic Imaging Ellipsometry for Opto-VLSI Engineering and Nanotechnology Applications. The focus for implementation of spectroscopic imaging ellipsometry is to create a powerful optical analysis and characterisation tool to complement the advanced integrated circuit test facilities within Western Australia. This infrastructure will facilitate the integration of the fields of materials research, new device technologies, integrated circuit technology, nanotechnology and photonics in the expanding field of Opto-VLSI. The proposed equipment is being built upon targeted research in VLSI, and will create an additional platform for innovations in microelectronic technology applicable to the communications, information technology, energy generation, security, and biomedical fields.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101032
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Electronics of the future: self-powering wireless circuit design. The aim of this project is to build a foundation for ultra-low-power wireless circuit design using technologies other than silicon. Scaling of transistors in silicon has been pushed to its limit and is of marginal benefit for low-power wireless circuit design. This project aims to address these limits by developing energy-efficient technology for wireless applications. The intended outcome of this project will be a self-powered, h ....Electronics of the future: self-powering wireless circuit design. The aim of this project is to build a foundation for ultra-low-power wireless circuit design using technologies other than silicon. Scaling of transistors in silicon has been pushed to its limit and is of marginal benefit for low-power wireless circuit design. This project aims to address these limits by developing energy-efficient technology for wireless applications. The intended outcome of this project will be a self-powered, high data rate receiver that will be critical in 5th-generation wireless systems. This could be used for a range of innovative wireless applications, for example in health care and environmental monitoring.Read moreRead less
Autonomous body sensors in humans: investigating new bio-sensing techniques with self-power generation. Using advanced integrated electronic and mechanical systems, it is now possible to design small biomedical sensors that can be inserted into the body to take biological measurements. This project introduces a new kind of bio-sensors with self-energy generation capability and reduces the need for periodic battery replacement. New wireless and circuit techniques are investigated to reduce power ....Autonomous body sensors in humans: investigating new bio-sensing techniques with self-power generation. Using advanced integrated electronic and mechanical systems, it is now possible to design small biomedical sensors that can be inserted into the body to take biological measurements. This project introduces a new kind of bio-sensors with self-energy generation capability and reduces the need for periodic battery replacement. New wireless and circuit techniques are investigated to reduce power consumption and physical dimensions, while providing a better performance and a safer wireless link. The project aims to deliver high level of comfort, better mobility and better patient care.Read moreRead less
Biomimetic Ultra-Thin Compound-Eye Vision Sensor. With the recent advances in microelectronic fabrication technology, it becomes possible today to fabricate paper-thin imaging systems. The proposed research will target the development of such systems to enable the concept of 'stick-on cameras'. Examples of potential applications for this new imaging technology include head-mounted camera patches for rescue workers, smart credit card capable of identifying its user by fingerprint technology, disc ....Biomimetic Ultra-Thin Compound-Eye Vision Sensor. With the recent advances in microelectronic fabrication technology, it becomes possible today to fabricate paper-thin imaging systems. The proposed research will target the development of such systems to enable the concept of 'stick-on cameras'. Examples of potential applications for this new imaging technology include head-mounted camera patches for rescue workers, smart credit card capable of identifying its user by fingerprint technology, discrete monitoring of venues, preventing driver's drowsiness inside a car but also assisting in medical diagnosis and minimally invasive surgery. This leading edge research will enhance the reputation of Australia as a leader in frontier technologies.Read moreRead less
Electronic Auditory Pathway. We will develop electronic building blocks to investigate biological signal processing. In particular, we will investigate the auditory pathway and develop the most accurate electronic model of the biological cochlea and auditory nerve. These will be followed by electronic circuits that model the processing of sensory signals in the brain. Processing signals with neural spikes offers distinct advantages over current analogue and digital signal processing techniques i ....Electronic Auditory Pathway. We will develop electronic building blocks to investigate biological signal processing. In particular, we will investigate the auditory pathway and develop the most accurate electronic model of the biological cochlea and auditory nerve. These will be followed by electronic circuits that model the processing of sensory signals in the brain. Processing signals with neural spikes offers distinct advantages over current analogue and digital signal processing techniques in terms of noise, energy consumption and extraction of temporal information. We will implement the first spike-based models of pitch and timbre perception, and a neural model of speech recognition in noisy environments.Read moreRead less