Australian Laureate Fellowships - Grant ID: FL130100041
Funder
Australian Research Council
Funding Amount
$3,094,000.00
Summary
The electro-photonic interchange: a new green platform for communications signal processing. This project will deliver the science for a new generation of green optical networks, by identifying optimum combinations of electronic and photonic signal processing to solve fundamental data bottlenecks. This project will implement these technologies in powerful electro-photonic chips, upon which superior energy-efficient internet switches can be built.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100203
Funder
Australian Research Council
Funding Amount
$420,000.00
Summary
Ultrafast optoelectronic characterisation for optical and wireless systems. Ultra-fast optoelectronic characterisation for optical and wireless systems:
The project aims to establish an ultra-fast optoelectronic characterisation facility to measure a wide range of electronic and photonic signals, providing versatile tools for conducting research on ultra-high-speed optical communications, microwave photonics, and millimetre wave systems. There is an increasing need for parallel signalling using ....Ultrafast optoelectronic characterisation for optical and wireless systems. Ultra-fast optoelectronic characterisation for optical and wireless systems:
The project aims to establish an ultra-fast optoelectronic characterisation facility to measure a wide range of electronic and photonic signals, providing versatile tools for conducting research on ultra-high-speed optical communications, microwave photonics, and millimetre wave systems. There is an increasing need for parallel signalling using spatial, temporal and spectral degrees of freedom in both radio-frequency and optical communications. The facility expects to leverage the recent rapid advances in powerful silicon digital signal processors with unprecedented capabilities in bandwidth and accuracy and focus on detecting massively parallel signals. The project aims to support a wide range of research activities from sustaining the phenomenal Internet growth in telecommunications to strengthening Australia’s defence systems.Read moreRead less
Rainbows on demand: coherent comb sources on a photonic chip. This project aims to create photonic circuit technologies that will generate hundreds of coherent laser lines from a single chip. The emerging industrially scalable silicon nitride on thin-film lithium niobate platform will be advanced to create resonant modulators and nonlinear waveguides with unprecedented efficiency and innovative monitoring and control techniques. When combined, these components will enable highly flexible and rob ....Rainbows on demand: coherent comb sources on a photonic chip. This project aims to create photonic circuit technologies that will generate hundreds of coherent laser lines from a single chip. The emerging industrially scalable silicon nitride on thin-film lithium niobate platform will be advanced to create resonant modulators and nonlinear waveguides with unprecedented efficiency and innovative monitoring and control techniques. When combined, these components will enable highly flexible and robust systems for generating a comb of coherent laser lines. These photonic chip comb sources will be inexpensive, compact and energy efficient with transformative impact in spectroscopy, microscopy, precision measurement, quantum computing and ultra-fast optical fibre communications.Read moreRead less
Breaking the glass ceiling: silicon-nitride (SiN) and doped silica glass for ultra high speed Complementary metal-oxide-semiconductor (CMOS) compatible optical processing and measurement chips. The global internet demands for energy and technology will soon be unsustainable. This project will pioneer faster, cheaper, far smaller, and more energy efficient optical signal processing and measurement chips compatible with silicon CMOS technology, for applications in telecommunications, silicon integ ....Breaking the glass ceiling: silicon-nitride (SiN) and doped silica glass for ultra high speed Complementary metal-oxide-semiconductor (CMOS) compatible optical processing and measurement chips. The global internet demands for energy and technology will soon be unsustainable. This project will pioneer faster, cheaper, far smaller, and more energy efficient optical signal processing and measurement chips compatible with silicon CMOS technology, for applications in telecommunications, silicon integrated circuits, and fundamental science.Read moreRead less
CMOS compatible nonlinear photonic integrated circuits. Bandwidth and energy demands of telecommunications networks are rapidly reaching a crisis point technologically, economically and from a sustainability viewpoint. At the same time, on-chip interconnects for silicon integrated circuits are also reaching a bottleneck. This project aims to combine the expertise of eight leading international groups to pioneer nonlinear photonic integrated circuits compatible with silicon technology (Complement ....CMOS compatible nonlinear photonic integrated circuits. Bandwidth and energy demands of telecommunications networks are rapidly reaching a crisis point technologically, economically and from a sustainability viewpoint. At the same time, on-chip interconnects for silicon integrated circuits are also reaching a bottleneck. This project aims to combine the expertise of eight leading international groups to pioneer nonlinear photonic integrated circuits compatible with silicon technology (Complementary Metal Oxide Semiconductor technology, or CMOS) to achieve new capabilities on a chip for signal generation, processing and measurement for telecommunications, computers, and fundamental science. These platforms are expected to allow the integration of electronics with photonics and to be faster, cheaper, smaller, and more energy efficient than current technology.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
Digitally controlled mm-wave band selective devices and MEMS technology. This project aims to develop millimetre-wave frequency selective devices with programmable frequency response, using a silicon technology platform. It will design and make an entire radio system, including its tuneable antenna, at the wafer level. Wafer scale integration ensures the devices are compact and low cost, and can be inserted into smart watches for touchless gesture control, and minuscule devices, too small to be ....Digitally controlled mm-wave band selective devices and MEMS technology. This project aims to develop millimetre-wave frequency selective devices with programmable frequency response, using a silicon technology platform. It will design and make an entire radio system, including its tuneable antenna, at the wafer level. Wafer scale integration ensures the devices are compact and low cost, and can be inserted into smart watches for touchless gesture control, and minuscule devices, too small to be connected to the internet today. The project will demonstrate its devices in a wireless communication system operating at unprecedented data rates of over 100 Gb/s. These could transform terrestrial and satellite communication systems and propel Australia to the forefront of wireless communications.Read moreRead less
Discreet reading of printable multi-bit chipless radio frequency identification (RFID) tags on polymer banknotes. Counterfeiting of banknotes is a serious and costly world-wide problem, and very sophisticated measures are necessary to thwart counterfeiters. This project will use radio frequency identification techniques to enable bank tellers and other staff handling cash to discreetly check banknotes as they count them in front of customers.
A new spectrum access technology for future wireless terminals. This project will develop a new frequency flexible wireless transceiver structure for the next generation of smartphones and wireless devices. The project will improve the roaming experience of travellers and reduce the cost of wireless connectivity, enabling new applications such as machine-to-machine communications and the internet-of-things.
Technology optimisation of integrated circuits with applications to wireless communication systems in medicine. This project will define and verify methods to help engineers pick the best technology for designing critical wireless monitoring systems used for medical devices. This project will also verify these methods by developing a wireless, implantable blood pressure monitor with real-time video.