Next-generation Navigation by Mega-constellations LEO Satellites. This research will explore a novel positioning approach using new mega-constellations low-earth-orbit satellite communications signals to address a severe limitation of Global Navigation Satellite Systems (GNSS). It will facilitate improved positioning for services that rely on satellite positioning in challenging environments where GNSS signal visibility is limited, and where accurate positioning is needed. Expected outcomes are ....Next-generation Navigation by Mega-constellations LEO Satellites. This research will explore a novel positioning approach using new mega-constellations low-earth-orbit satellite communications signals to address a severe limitation of Global Navigation Satellite Systems (GNSS). It will facilitate improved positioning for services that rely on satellite positioning in challenging environments where GNSS signal visibility is limited, and where accurate positioning is needed. Expected outcomes are generating new knowledge in using satellite internet signals for navigation, advancing our satellite positioning capability essential for vital applications such as transport, mining and defence, and developing technologies to increase Australia’s satellite innovation capacity with global scalability.Read moreRead less
Tracking formation-flying of nanosatellites using inter-satellite links. This project aims to realise real-time kinematic precise orbit and attitude determination of nano satellites. Formation flying, based on distributed miniaturised satellites such as Cubesats, is envisioned to revolutionise the way the space-science community conducts autonomous missions. The project will develop a purely kinematic concept exploiting the full capabilities of Global Navigation Satellite Systems (GNSS) carrier- ....Tracking formation-flying of nanosatellites using inter-satellite links. This project aims to realise real-time kinematic precise orbit and attitude determination of nano satellites. Formation flying, based on distributed miniaturised satellites such as Cubesats, is envisioned to revolutionise the way the space-science community conducts autonomous missions. The project will develop a purely kinematic concept exploiting the full capabilities of Global Navigation Satellite Systems (GNSS) carrier-phase measurements for instantaneous precise orbit and attitude determination of the Cubesats. The project will also pioneer the use of the satellite based augmentation systems (SBAS), supporting the future Australian SBAS program, and the development of integrated algorithms for space-based, Precise Point Positioning with fixed ambiguities supported by SBAS.Read moreRead less
A Self-Repairing Entropy-Stabilized Oxide as a Protective Coating. All biological organisms, from plants to living creatures, can heal minor wounds and damages. Based on the recent breakthrough by the CI’s team, this project aims to design and develop a new oxide containing multiple elements in a form of (AlCoCrCu0.5FeNi)3O4 that can resist damages through a self-repairing mechanism. Fabricated by radio frequency (RF) magnetron sputtering, this extraordinary self-repairing phenomenon makes this ....A Self-Repairing Entropy-Stabilized Oxide as a Protective Coating. All biological organisms, from plants to living creatures, can heal minor wounds and damages. Based on the recent breakthrough by the CI’s team, this project aims to design and develop a new oxide containing multiple elements in a form of (AlCoCrCu0.5FeNi)3O4 that can resist damages through a self-repairing mechanism. Fabricated by radio frequency (RF) magnetron sputtering, this extraordinary self-repairing phenomenon makes this new material highly desirable as a coating to protect structures and machinery working in hash conditions. Therefore, it has broad applications in space technologies, nuclear power facilities and aerospace industry, as well as in shipbuilding industry. Read moreRead less
Micro-electro-mechanical Technologies and Tuneable Millimetre-wave Systems. The project aims to develop background theory and microelectromechanical (MEM)-based techniques for monolithic fabrication that integrate highly miniaturised three-dimensional waveguides with MEM systems. These technologies shall be used to design, develop and fabricate reconfigurable millimetre-wave devices. The project aims to bring together micromachining and millimetre-wave circuits to enable the realisation of recon ....Micro-electro-mechanical Technologies and Tuneable Millimetre-wave Systems. The project aims to develop background theory and microelectromechanical (MEM)-based techniques for monolithic fabrication that integrate highly miniaturised three-dimensional waveguides with MEM systems. These technologies shall be used to design, develop and fabricate reconfigurable millimetre-wave devices. The project aims to bring together micromachining and millimetre-wave circuits to enable the realisation of reconfigurable systems on chip. These technologies offer reduced size, cost and power consumption and high functionality, unachievable with conventional millimetre wave technology alone. The planned outcomes of the project are necessary to satisfy the sharply risen requirements for current and future fourth and fifth generation (4G and 5G) wireless communications systems.Read moreRead less
Scalable nanomechanical information processing. This project aims to build the first scalable computer architecture based on nanoscale motion on a silicon chip. Such nanomechanical computers could extend computing performance in space and earth-orbit applications, and in other environments where intense radiation causes digital electronics to fail. The project intends to utilise recent advances in nanomechanics and nanofabrication to demonstrate all key nanomechanical circuit elements, including ....Scalable nanomechanical information processing. This project aims to build the first scalable computer architecture based on nanoscale motion on a silicon chip. Such nanomechanical computers could extend computing performance in space and earth-orbit applications, and in other environments where intense radiation causes digital electronics to fail. The project intends to utilise recent advances in nanomechanics and nanofabrication to demonstrate all key nanomechanical circuit elements, including transistors, logic gates, memories and analogue-to-digital converters and to deliver a roadmap for commercialisation of the technology in Australia. The expected outcome of this project is the development of the underpinning nanotechnologies, predicted to have wide uses in sensing, health and communications,and which could improve heat management and energy efficiency in future computers. This new approach to computing has potential for near-term commercial impact in the aerospace industry, building on Australian know-how.Read moreRead less
Scalable and reversible computing with integrated nanomechanics. This project aims to build the first scalable computing architecture based on nanomechanical motion, integrated on a silicon chip and proven in harsh environments. This could extend the performance of computers in space and high-radiation environments, e.g. allowing robust satellite stabilisation. The project will leverage our know-how in phononics and nanofabrication to enable previously unprecedented control of nanomechanical mot ....Scalable and reversible computing with integrated nanomechanics. This project aims to build the first scalable computing architecture based on nanomechanical motion, integrated on a silicon chip and proven in harsh environments. This could extend the performance of computers in space and high-radiation environments, e.g. allowing robust satellite stabilisation. The project will leverage our know-how in phononics and nanofabrication to enable previously unprecedented control of nanomechanical motion, and exquisitely low energy dissipation. It aims to construct a nanomechanical processor capable of digital servo control, built from nanomechanical waveguides, transistors, logic gates and analogue-to-digital converters. It will also develop reversible logic gates, a key step towards ultralow-power computing.Read moreRead less
A Dual-species Ion Trap with Precision Optical Clocks. This project will enable new technological capabilities to overcome challenges in scaling up quantum computation and advancing quantum clocks. It will develop a versatile dual-species atomic instrumentation paired with precision laser systems. This advanced technological platform will be augmented by an extensive toolbox of quantum control engineering protocols to perform error-robust quantum operations for fault-tolerant quantum computation ....A Dual-species Ion Trap with Precision Optical Clocks. This project will enable new technological capabilities to overcome challenges in scaling up quantum computation and advancing quantum clocks. It will develop a versatile dual-species atomic instrumentation paired with precision laser systems. This advanced technological platform will be augmented by an extensive toolbox of quantum control engineering protocols to perform error-robust quantum operations for fault-tolerant quantum computation and high-precision spectroscopy. The expected outcomes will also benefit other disciplines: advanced quantum simulations for chemical dynamics, precision spectroscopy for astronomy, next-generation lasers, tests of fundamental physics, and quantum-enhanced positioning, navigation, and timing. Read moreRead less
Catching the fast waves: high speed RF sensing using Brillouin scattering. This project aims to develop a room temperature approach to fast sensing of microwave electromagnetic waves by harnessing stimulated Brillouin Scattering (SBS), simultaneously achieving high frequency range, high resolution and high-speed performance. This project expects to generate new knowledge in microwave photonics and SBS, specifically elucidating the transient temporal response of SBS. Expected outcomes of this pro ....Catching the fast waves: high speed RF sensing using Brillouin scattering. This project aims to develop a room temperature approach to fast sensing of microwave electromagnetic waves by harnessing stimulated Brillouin Scattering (SBS), simultaneously achieving high frequency range, high resolution and high-speed performance. This project expects to generate new knowledge in microwave photonics and SBS, specifically elucidating the transient temporal response of SBS. Expected outcomes of this project include a proof of concept RF sensor that has multi-Gigahertz real-rime instantaneous bandwidth with high-resolution that can be miniaturized on to a chip. This compact RF sensor, will play a vital role for situational awareness in space, defence and communications applications. Read moreRead less