Millimetre Wave Communication Systems for Consumer Applications. The key outcome of this cross-disciplinary project will be a prototype single-chip (RF section), short-range, 1Gigabit/second, wireless network operating at 60 GHz. This will employ new Silicon Germanium technology in a 'system on chip' methodology that will pave the way for low-cost consumer applications of such technology. A new design flow will be developed to support this project, which will enable first silicon pass correct d ....Millimetre Wave Communication Systems for Consumer Applications. The key outcome of this cross-disciplinary project will be a prototype single-chip (RF section), short-range, 1Gigabit/second, wireless network operating at 60 GHz. This will employ new Silicon Germanium technology in a 'system on chip' methodology that will pave the way for low-cost consumer applications of such technology. A new design flow will be developed to support this project, which will enable first silicon pass correct design of complete mm-wave millimetre wave radios on a single chip, a feat that has yet to be demonstrated. A new communication system will be developed to support the high data rates proposed. The significance will be application in very high speed high-bandwith wireless local networks.Read moreRead less
Silicon Photonics and Third Generation Photovoltaics. The Fellowship would be used to launch a major new initiative addressing one of the key challenges facing microelectronics, the incorporation of optical functions into high density silicon integrated circuits, as well as accelerating development of a "third" generation of photovoltaic solar cells using similar techniques. This third generation thin-film technology would be capable of fundamentally higher energy conversion efficiency than ear ....Silicon Photonics and Third Generation Photovoltaics. The Fellowship would be used to launch a major new initiative addressing one of the key challenges facing microelectronics, the incorporation of optical functions into high density silicon integrated circuits, as well as accelerating development of a "third" generation of photovoltaic solar cells using similar techniques. This third generation thin-film technology would be capable of fundamentally higher energy conversion efficiency than earlier generations, at low cost. In both cases, the targeted outcome over the period of the Fellowship is to develop technology to the stage where it can be commercially evaluated, in a way likely to maximise Australian benefits.Read moreRead less
Design Methodology for Low- and Ultra-Low Power Integrated Circuits. This project will develop low-power and ultra low-power technology that is applicable to wide range of products and electronic devices. The results will benefit many areas, for example, wireless sensors employed in environmental monitoring, bio and life monitoring, bio-sensors to improve patient care, reduce medical costs, implantable devices and bio-interfaces that will enhance the quality of life and public health. This proje ....Design Methodology for Low- and Ultra-Low Power Integrated Circuits. This project will develop low-power and ultra low-power technology that is applicable to wide range of products and electronic devices. The results will benefit many areas, for example, wireless sensors employed in environmental monitoring, bio and life monitoring, bio-sensors to improve patient care, reduce medical costs, implantable devices and bio-interfaces that will enhance the quality of life and public health. This project will benefit Australia by developing frontier technologies with a strong potential for global impact. Bringing these solutions to the public and realizing their financial benefits will add a valuable component of economic diversity to the country in addition to positioning Australia as a leader in this field.Read moreRead less
Microelectronic Applications of Improved Silicon Light Emission. While semiconductor silicon chips have been the workhorse of the microelectronics revolution, more complex semiconductor materials have driven the communications revolution. Australian developments during 2001 have largely dispelled the myth that silicon is fundamentally a poor emitter of light. This project aims to build on this work by developing silicon light emitters suitable for integration into high density integrated circu ....Microelectronic Applications of Improved Silicon Light Emission. While semiconductor silicon chips have been the workhorse of the microelectronics revolution, more complex semiconductor materials have driven the communications revolution. Australian developments during 2001 have largely dispelled the myth that silicon is fundamentally a poor emitter of light. This project aims to build on this work by developing silicon light emitters suitable for integration into high density integrated circuits, adding a new dimension to the capabilities of these circuits, driving microelectronics and the information age to the next stage of development.Read moreRead less
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
Dynamic signal processing with currents. Today's digital computers and communications devices, such as mobile phones, contain continuous time filters as necessary and important components. We will investigate an integrated circuit design methodology for the creation of fully programmable versions of such filters. Currently these filters are redesigned for each application and are often external to the IC. This increases the size and cost of the design. Another outcome of the methodology is a cur ....Dynamic signal processing with currents. Today's digital computers and communications devices, such as mobile phones, contain continuous time filters as necessary and important components. We will investigate an integrated circuit design methodology for the creation of fully programmable versions of such filters. Currently these filters are redesigned for each application and are often external to the IC. This increases the size and cost of the design. Another outcome of the methodology is a current domain signal processor. This will be capable of modelling complex systems such as biological neurons and stock option pricing. We will build these systems and interface them with digital computers.Read moreRead less
Centre for Advanced Silicon Photovoltaics and Photonics. Silicon photovoltaics (Si PV) is a priority area within the Photon Science and Technology category. Multiple studies have identified PV solar electricity as the most promising option for a sustainable energy future, with Australia already at the forefront internationally in Si PV. The applicants recently have shown that insights from PV also may provide the key to the successful development of active Si photonic devices for integration i ....Centre for Advanced Silicon Photovoltaics and Photonics. Silicon photovoltaics (Si PV) is a priority area within the Photon Science and Technology category. Multiple studies have identified PV solar electricity as the most promising option for a sustainable energy future, with Australia already at the forefront internationally in Si PV. The applicants recently have shown that insights from PV also may provide the key to the successful development of active Si photonic devices for integration into microelectronics. The Centre's aims and expected outcomes are to strengthen this technological lead in Si PV while pioneering the development of active Si photonic devices for microelectronic integration, with economic, cultural and social benefits.Read moreRead less
A neuromorphic binaural hearing sensor. A neuromorphic binaural hearing sensor will be created. The system includes two cochleae and targeted processing pathways in the auditory brainstem that aid in solving the Cocktail Party Problem: i.e. foreground-background sound separation, sound localisation, and sound recognition. The VLSI circuits will enable real-time implementation of complex auditory models. As we develop our VLSI binaural ear, we will experiment with afferent (feed forward) and ....A neuromorphic binaural hearing sensor. A neuromorphic binaural hearing sensor will be created. The system includes two cochleae and targeted processing pathways in the auditory brainstem that aid in solving the Cocktail Party Problem: i.e. foreground-background sound separation, sound localisation, and sound recognition. The VLSI circuits will enable real-time implementation of complex auditory models. As we develop our VLSI binaural ear, we will experiment with afferent (feed forward) and efferent (feed back) auditory signal processing that is similar to real auditory systems and that demonstrate efficient, effective, and low-power signal processing algorithms for binaural (two-sensor) hearing systems.Read moreRead less
Special Research Initiatives - Grant ID: SR0354735
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Australian Network on Microelectronics, Optoelectronics and Microelectromechanical Systems. The Network will encompass semiconductor microelectronics, optoelectronics, sensors and microelectromechanical systems (MEMS). Fundamental research in these areas enables the technological advances that underpin rapidly developing industries such as information and telecommunications technologies, defence, aerospace, medicine, and remote sensing. Exciting challenges exist in designing new devices that exp ....Australian Network on Microelectronics, Optoelectronics and Microelectromechanical Systems. The Network will encompass semiconductor microelectronics, optoelectronics, sensors and microelectromechanical systems (MEMS). Fundamental research in these areas enables the technological advances that underpin rapidly developing industries such as information and telecommunications technologies, defence, aerospace, medicine, and remote sensing. Exciting challenges exist in designing new devices that exploit unique semiconductor systems and technologies. By sharing capabilities and resources (both capital and human), the network will enable the issues associated with such novel materials and devices to be addressed in a targeted manner. The network will also guarantee the ongoing future of research in the area by actively involving early career researchers and postgraduate students.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