Microfabrication of integrated silicon optical cross-switches interfaced with silica optical waveguides. Project aims to fabricate novel silicon based optical switches in the form of cantilevered mirrors integrated to interface with silica optical waveguides integrated collimation lens. Significantly, it paves the way for low cost integration of optical switches with array waveguides for an all-optical dynamically reconfigurable dense wavelength division multiplexing network used in modern broad ....Microfabrication of integrated silicon optical cross-switches interfaced with silica optical waveguides. Project aims to fabricate novel silicon based optical switches in the form of cantilevered mirrors integrated to interface with silica optical waveguides integrated collimation lens. Significantly, it paves the way for low cost integration of optical switches with array waveguides for an all-optical dynamically reconfigurable dense wavelength division multiplexing network used in modern broadband telecommunication systems. International market demand for such devises is enormous. Expected outcomes include the development of arrays of low loss 2x2 integrated optical waveguide cross-switches prototypes, securing the intellectual property rights and disseminating the work internationally.Read moreRead less
Miniaturised Adiabatic Light Processing Devices. The project will develop, model and analyse a range of miniaturised light-processing devices for optical communications applications that rely soley on their geometrical design for their optical functionality. Such devices are less complex than devices that rely on other physical phenomena for their operation, such as interference, resonance or grating phenomena. They have potential application to a wide range of applications including optical tel ....Miniaturised Adiabatic Light Processing Devices. The project will develop, model and analyse a range of miniaturised light-processing devices for optical communications applications that rely soley on their geometrical design for their optical functionality. Such devices are less complex than devices that rely on other physical phenomena for their operation, such as interference, resonance or grating phenomena. They have potential application to a wide range of applications including optical telecommunications, optical sensing and biophotonics. The major outcome will be a range of novel devices that are very compact, have very low optical power loss and process light signals in ways that either cannot be readily achieved by other approaches or are simpler than other approaches.Read moreRead less
Special Research Initiatives - Grant ID: SR0354721
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Frontier and Security Technologies Microfabrication Network. This Initiative will conduct a comprehensive survey of Australia's resources in micro-fabrication, a key enabling technology for two national research priority areas, and generate new collaboration opportunities that capitalise on this resource base and open it to a wider range of applications. The Initiative will focus on photonics, nano-materials and security applications, and will identify gaps in micro-fabrication capabilities requ ....Frontier and Security Technologies Microfabrication Network. This Initiative will conduct a comprehensive survey of Australia's resources in micro-fabrication, a key enabling technology for two national research priority areas, and generate new collaboration opportunities that capitalise on this resource base and open it to a wider range of applications. The Initiative will focus on photonics, nano-materials and security applications, and will identify gaps in micro-fabrication capabilities required to support research in these areas. The outcomes will be a key element in a national strategic plan for these areas of national priority. The web site will demonstrate key features of the IT-based support features of a micro-fabrication network.Read moreRead less
Tools and techniques for cost effective creation of new, reliable and efficient microwave transistors for millimetre wave and wireless applications. Shifting the circuit design paradigm to the requirements of a circuit will provide a low-cost design solution for application with tight size, performance and lifetime constraints. This will enhance the international competitiveness of Mimix Broadband in the microwave wireless, aerospace, and radar markets, which will contribute to Australia's high ....Tools and techniques for cost effective creation of new, reliable and efficient microwave transistors for millimetre wave and wireless applications. Shifting the circuit design paradigm to the requirements of a circuit will provide a low-cost design solution for application with tight size, performance and lifetime constraints. This will enhance the international competitiveness of Mimix Broadband in the microwave wireless, aerospace, and radar markets, which will contribute to Australia's high performance circuit design sector. New knowledge and skilled researchers provided by this project will foster growth of the microwave and wireless industry. The local research community will be advantaged in international reputation and in its efforts to develop future high performance wireless systems.Read moreRead less
Overcoming Transistor Performance Issues for Emerging Millimetre-Wave Applications. The operation of transistors for emerging millimeter-wave applications, such as point to point communications and automotive radar, will be researched. The aim is to develop circuit design methodologies that extract better performance from a given fabrication process, thus giving a competitive advantage to local industry, which shares the process with other international companies. Transistor operating range, lin ....Overcoming Transistor Performance Issues for Emerging Millimetre-Wave Applications. The operation of transistors for emerging millimeter-wave applications, such as point to point communications and automotive radar, will be researched. The aim is to develop circuit design methodologies that extract better performance from a given fabrication process, thus giving a competitive advantage to local industry, which shares the process with other international companies. Transistor operating range, linearity and characterisation will be enhanced. New models and demonstrator circuits will be produced. The project will skill postgraduates in microwave theory and techniques applied to the development of high performance circuits.Read moreRead less
Future generation high-performance radio communications circuits in gallium nitride technology. Techniques will be developed to exploit the potential of an emerging commercial gallium nitride technology for future communication systems. By establishing new knowledge and skill to expand international competitiveness, it will position Australia among the leaders in high performance circuit design, strengthen international collaboration, and allow the development of future high performance wireless ....Future generation high-performance radio communications circuits in gallium nitride technology. Techniques will be developed to exploit the potential of an emerging commercial gallium nitride technology for future communication systems. By establishing new knowledge and skill to expand international competitiveness, it will position Australia among the leaders in high performance circuit design, strengthen international collaboration, and allow the development of future high performance wireless systems. This is an opportunity to diversify to a new technology on a competitive basis. This circuit design business is suited to distance working within the international sector. Improved circuit performance will enable breakthrough discoveries in areas like medical imaging, radar, detection, and instrumentation.Read moreRead less
Achieving high linearity over broad bands in transistor circuits for communication applications. This project provides techniques to achieve the distortion performance required for the next generation communication circuits. By establishing new knowledge and skill within Australia to expand international competitiveness, it will position Australia as the leader in high performance circuit design, strengthen international collaboration, and allow the development of high performance broadband syst ....Achieving high linearity over broad bands in transistor circuits for communication applications. This project provides techniques to achieve the distortion performance required for the next generation communication circuits. By establishing new knowledge and skill within Australia to expand international competitiveness, it will position Australia as the leader in high performance circuit design, strengthen international collaboration, and allow the development of high performance broadband systems. An opportunity will be presented to enter the transistor characterization market on a competitive basis, which is a business suited to distance working within the international sector. Improved circuit performance will enable breakthrough discoveries in areas like radio astronomy, medical imaging, radar and detection, and instrumentation.Read moreRead less
RNS Hardware for Public-Key Cryptography and E-security. In a world where electronic communication is ever-present, the security of electronic information, e-security, is an issue of the utmost concern for government, business and individuals alike. Public-key cryptography is a powerful tool in the e-security toolkit. Using this technology it is possible to confirm the identity of individuals, maintain the privacy of personal data and guarantee the authenticity of transactions.
The aim of this ....RNS Hardware for Public-Key Cryptography and E-security. In a world where electronic communication is ever-present, the security of electronic information, e-security, is an issue of the utmost concern for government, business and individuals alike. Public-key cryptography is a powerful tool in the e-security toolkit. Using this technology it is possible to confirm the identity of individuals, maintain the privacy of personal data and guarantee the authenticity of transactions.
The aim of this project is to design new public-key cryptography hardware to provide faster, more secure communications for computers, networks and smart cards. Achieving this will require innovations in the way computers perform arithmetic and how this arithmetic is realised as an integrated circuit.Read moreRead less
Hardware Implementation Strategies for JPEG 2000. JPEG2000 is a new image compression standard, which is expected to become the dominant format for image communications over the internet and then make inroads into consumer peripheral devices, including digital cameras, printers and scanners. The standard is fundamentally different from and much more complex than its well-known predecessor, JPEG, and there are currently no published hardware implementations. The aim of this project is to investig ....Hardware Implementation Strategies for JPEG 2000. JPEG2000 is a new image compression standard, which is expected to become the dominant format for image communications over the internet and then make inroads into consumer peripheral devices, including digital cameras, printers and scanners. The standard is fundamentally different from and much more complex than its well-known predecessor, JPEG, and there are currently no published hardware implementations. The aim of this project is to investigate a wide range of potential implementation strategies to identify those which are able to minimize the consumption of various resources, including memory consumption, memory bandwidth, chip area and processing latency.Read moreRead less
New Methods and Microelectronics for Wireless Communication Systems. Global demand for high quality wireless communications poses significant challenges. The so-called "physical layer" is crucial, as this is where the vagaries of the wireless channel, including interference and limited bandwidth, are mitigated by sophisticated signal processing.
This project will conduct applied research to meet these physical layer challenges, providing solutions that feed directly into next generation wirel ....New Methods and Microelectronics for Wireless Communication Systems. Global demand for high quality wireless communications poses significant challenges. The so-called "physical layer" is crucial, as this is where the vagaries of the wireless channel, including interference and limited bandwidth, are mitigated by sophisticated signal processing.
This project will conduct applied research to meet these physical layer challenges, providing solutions that feed directly into next generation wireless communication systems.
Uniquely, this project focuses on the transfer of research from theoretical genesis, through to realisation of silicon integrated
circuit "chips". This will maximise both the impact of the research
and the potential for significant national economic benefits to accrue.Read moreRead less