Development of the next generation battery storage system for smart grid. Development of the next generation battery storage system for smart grid. This project aims to significantly improve the energy density, safety and robust storage performance of lithium batteries with reduced cost, by developing a next-generation battery with lithium-rich layered oxide cathodes and titanium oxide-based and silicon-based anodes. Intelligent features will make the whole energy network a next-generation batte ....Development of the next generation battery storage system for smart grid. Development of the next generation battery storage system for smart grid. This project aims to significantly improve the energy density, safety and robust storage performance of lithium batteries with reduced cost, by developing a next-generation battery with lithium-rich layered oxide cathodes and titanium oxide-based and silicon-based anodes. Intelligent features will make the whole energy network a next-generation battery storage system, with mechanisms to protect the battery from hazardous and inefficient operating conditions. This lithium ion battery storage system is expected to create opportunities for businesses that harvest renewable energy and make existing industries more environmentally benign.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
Photonic chip inertial movement sensors. This project aims to create a new class of optical inertial movement sensors using integrated photonic chip technology. By replacing optical fibre coils with compact waveguides, integrating light sources on-chip and by harnessing smart sensing approaches, we intend to reduce the required power from watts to milliwatts and reduce the dimensions from meters to centimetres. The expected project outcomes are sensors with military grade precision but with the ....Photonic chip inertial movement sensors. This project aims to create a new class of optical inertial movement sensors using integrated photonic chip technology. By replacing optical fibre coils with compact waveguides, integrating light sources on-chip and by harnessing smart sensing approaches, we intend to reduce the required power from watts to milliwatts and reduce the dimensions from meters to centimetres. The expected project outcomes are sensors with military grade precision but with the size, cost and manufacturability of consumer electronics. This technology will fill a strategic gap in the movement sensor market enabling applications ranging from robotic infrastructure monitoring, manufacture and surgery to guiding satellites and other space craft.Read moreRead less
Novel circuits and design strategies for sub-65 nanometre complementary metal oxide semiconductor technologies. This project will develop novel, state-of-the-art circuits and design strategies that overcome the challenges of current and future Integrated Circuit (IC) fabrication technologies. The extremely small sizes of transistors in these technologies offer advantages in speed, but at the price of a number of drawbacks, which the project will aim to overcome in this work. This research will m ....Novel circuits and design strategies for sub-65 nanometre complementary metal oxide semiconductor technologies. This project will develop novel, state-of-the-art circuits and design strategies that overcome the challenges of current and future Integrated Circuit (IC) fabrication technologies. The extremely small sizes of transistors in these technologies offer advantages in speed, but at the price of a number of drawbacks, which the project will aim to overcome in this work. This research will make a significant contribution to the field of IC design as well as providing training for students to fill the present and future needs of Australia's IC design companies. Some of the most advanced cochlear implants, mobile phone ICs, and Wireless Internet ICs have been designed in Australia, and companies in Australia desperately need graduates skilled in designing in the latest technologies.Read moreRead less
Auditory perception in neural electronics. This project aims to develop a practical alternative to conventional electronic design. Faster and more powerful devices have resulted from placing ever more transistors on a computer chip, but this is reaching its physical limits. This project will develop a new way of designing smart electronic devices by taking inspiration from signal processing in biological brains, and applying it to the processing of audio signals. Expected outcomes are a device t ....Auditory perception in neural electronics. This project aims to develop a practical alternative to conventional electronic design. Faster and more powerful devices have resulted from placing ever more transistors on a computer chip, but this is reaching its physical limits. This project will develop a new way of designing smart electronic devices by taking inspiration from signal processing in biological brains, and applying it to the processing of audio signals. Expected outcomes are a device that recognises sounds, without needing remote computers to do the processing. These techniques can be applied to other senses, such as vision, advancing machine perception and enabling smarter devices.Read moreRead less
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
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.
Hardware Acceleration for Neural Systems. To really understand how brains work, we need to simulate neural networks of a size similar to that of the human brain (100 billion neurons, 100 trillion connections). Simulating such a network on standard computers in not possible because of its sheer size. Several groups are currently building very expensive and proprietary hardware to solve this, but the output from these projects will not be accessible to other researchers. In order to make real prog ....Hardware Acceleration for Neural Systems. To really understand how brains work, we need to simulate neural networks of a size similar to that of the human brain (100 billion neurons, 100 trillion connections). Simulating such a network on standard computers in not possible because of its sheer size. Several groups are currently building very expensive and proprietary hardware to solve this, but the output from these projects will not be accessible to other researchers. In order to make real progress in neuroscience, many more researchers need to be enabled to participate. To do this, the project will build a system from commercial hardware (FPGAs) that will cost only a few ten thousand dollars and it will make this design and software available for free. Read moreRead less
Chip-scale implantable bionics for next generation therapeutic neural prostheses. Australia has an unmatched reputation as a world leader in neuroprostheses. Most notable of these is the bionic ear and, more recently, leading edge research towards a bionic eye. This project will combine the research strengths and experiences from both the hearing and visual bionics fields to address the main obstacles that prevent the number of electrical stimulation channels (equating to the number of frequenci ....Chip-scale implantable bionics for next generation therapeutic neural prostheses. Australia has an unmatched reputation as a world leader in neuroprostheses. Most notable of these is the bionic ear and, more recently, leading edge research towards a bionic eye. This project will combine the research strengths and experiences from both the hearing and visual bionics fields to address the main obstacles that prevent the number of electrical stimulation channels (equating to the number of frequencies heard by the deaf, and the number of spots of light seen by the blind) from increasing. The study will improve our understanding of the electrode-tissue interface, the life-long implantablity, and electrical circuitry that will allow future bionic devices to significantly improve their performance.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