Enhanced brain and muscle signal separation verified by electrical scalp recordings from paralysed awake humans. This project will develop algorithms to separate brain signals from muscle signals in electrical recordings from the scalp. Cleaner brain signal measurement enables improvements in understanding how the brain works, the diagnosis and management of neurological diseases, and the development of brain-controlled devices for very disabled people.
Combined Terahertz Imaging and Optical Coherence Tomography. This project aims to exploit the synergies between terahertz imaging and optical coherence tomography. These novel imaging modalities will be combined into a single multi-modality technique which will have application in numerous industry sectors like manufacturing, non-destructive testing, pharmaceutical and medicine. The intended outcome of the project is to create an internationally leading position for Australia in cutting-edge res ....Combined Terahertz Imaging and Optical Coherence Tomography. This project aims to exploit the synergies between terahertz imaging and optical coherence tomography. These novel imaging modalities will be combined into a single multi-modality technique which will have application in numerous industry sectors like manufacturing, non-destructive testing, pharmaceutical and medicine. The intended outcome of the project is to create an internationally leading position for Australia in cutting-edge research in optical and terahertz imaging. This innovative, fundamental research will expand Australia’s research capacity in imaging with wide ranging applications. The anticipated goal of the project is to build a prototype imaging system with industry partners ready for the next step to commercialisation. Read moreRead less
Pumping up the volume on sound-light interactions. This project aims to create a new class of integrated microwave information processors on a single optical chip. Using electro-acoustic coupling in semiconductors, we expect to reduce optical power requirements hundredfold, enabling the emergence of practically deployable processors using ordinary telecom lasers. The expected project outcomes are inexpensive, compact, stable and energy efficient microwave photonic processors, a key requirement f ....Pumping up the volume on sound-light interactions. This project aims to create a new class of integrated microwave information processors on a single optical chip. Using electro-acoustic coupling in semiconductors, we expect to reduce optical power requirements hundredfold, enabling the emergence of practically deployable processors using ordinary telecom lasers. The expected project outcomes are inexpensive, compact, stable and energy efficient microwave photonic processors, a key requirement for reference standards and precision measurements of time and frequency. This technology has the potential to create a multitude of opportunities for commercial development in the fields of defence, information security, autonomous vehicles, sensing, and ultra-high bandwidth mobile communications.Read moreRead less
Polymer fibres: A game changer for THz high-capacity interconnects. The transition to a society with consuming enormous amounts of digital data has accentuated the need for high-speed data links. The project aims to create a novel class of polymer terahertz fibres to replace the current lossy wires that are bandwidth limited. This will be achieved through innovative microstructured fibre designs, cost-effective and scalable fibre fabrication, and integration of terahertz fibre in the next genera ....Polymer fibres: A game changer for THz high-capacity interconnects. The transition to a society with consuming enormous amounts of digital data has accentuated the need for high-speed data links. The project aims to create a novel class of polymer terahertz fibres to replace the current lossy wires that are bandwidth limited. This will be achieved through innovative microstructured fibre designs, cost-effective and scalable fibre fabrication, and integration of terahertz fibre in the next generation communication systems. The project outcomes are expected to put Australia at the forefront of the field of polymer terahertz fibre links, which will be a game changer for industries that require reliable and high-speed connections including telecom, automotive, space, datacentres, and image processing.
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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
Breaking bandwidth barriers: Non-volatile tuneable terahertz metamaterials. This project aims to investigate non-volatile tuneable terahertz (THz) metamaterials, based on the exploitation of phase change materials. Tuneable metamaterial-based THz devices, such as filters and modulators, could generate significant downstream intellectual property for wireless applications. This fills a critical need to meet the increasing demand for greater bandwidth between desktop devices. Expected outcomes inc ....Breaking bandwidth barriers: Non-volatile tuneable terahertz metamaterials. This project aims to investigate non-volatile tuneable terahertz (THz) metamaterials, based on the exploitation of phase change materials. Tuneable metamaterial-based THz devices, such as filters and modulators, could generate significant downstream intellectual property for wireless applications. This fills a critical need to meet the increasing demand for greater bandwidth between desktop devices. Expected outcomes include understanding the interaction between THz signals and phase change materials, tuneable metamaterials, and devices that can steer and modulate THz signals with unprecedented agility and compactness, enabling future high-bandwidth Bluetooth-like data transfer.Read moreRead less
Collision Avoidance in Shipping Lanes via Intelligent Sensor Data Fusion . This project aims to develop an online maritime traffic monitoring system for reliable collision/contact avoidance that exploits complementary data from high-resolution airborne sensors and surface vessel sensors. Our approach is based on optimal scheduling and fusion of the sensor data and possibly other sources of data to construct a comprehensive dynamic picture of maritime traffic, in real-time. Moreover, the proposed ....Collision Avoidance in Shipping Lanes via Intelligent Sensor Data Fusion . This project aims to develop an online maritime traffic monitoring system for reliable collision/contact avoidance that exploits complementary data from high-resolution airborne sensors and surface vessel sensors. Our approach is based on optimal scheduling and fusion of the sensor data and possibly other sources of data to construct a comprehensive dynamic picture of maritime traffic, in real-time. Moreover, the proposed methodology enables quantification of confidence in the predictions. This will provide ship owners, directly to their vessels and/or at the fleet management centres, information such as weather reports, reliable collision/no-collision warnings and avoidance strategies, on-the-fly. Read moreRead less
Ultra-high spectral purity lasers for tests of relativity and atomic clocks. Measurement precision is the key to advancement of a technological society. This project aims to build the most precise measurement tool ever developed: one capable of delivering 17 digits of precision in just 1 second. In conjunction with German and French colleagues this too will be used to test the foundation theories of physics.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100109
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Raman Spectroscopic System for In-Operando Electrochemical Studies. This proposal aims to establish a Raman microscopic system with real-time tracking capability, which will allow investigation of the activities of battery components during charging. An instrument that allows this level of interrogation is currently not available in Australia. Expected outcomes include advanced knowledge for improved battery technology, which will meet the increasing demand of electronic applications and provide ....Raman Spectroscopic System for In-Operando Electrochemical Studies. This proposal aims to establish a Raman microscopic system with real-time tracking capability, which will allow investigation of the activities of battery components during charging. An instrument that allows this level of interrogation is currently not available in Australia. Expected outcomes include advanced knowledge for improved battery technology, which will meet the increasing demand of electronic applications and provide commercial opportunities in Australia. This system will be highly versatile and extendable to other fields of energy and materials-related research, providing high-quality training of researchers, as well as a platform from which to enhance materials research capabilities in Australia.Read moreRead less
Dynamic terahertz superlenses for sub-wavelength sensing and imaging. We propose to develop a 'dynamic terahertz superlens' that will dramatically enhance the performance of existing T-ray imaging systems used for biosensing of cells, DNA and proteins. The science of the superlens is remarkable in that it enables image resolution shorter than the wavelength.