Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100124
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Coherent detection based characterisation facility for ultra broadband photonic and RF systems. The new infrastructure will allow detection of ultrahigh-speed optical and wireless signals. The facility adopts coherent detection based technologies providing superior performance in resolution, sensitivity, and bandwidth. It will play an important role in supporting research activities to accommodate phenomenal Internet growth.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100160
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Distributed ultra-fast optical clocks for terabit/s communications. The project aims to enable experiments with full spectrum occupation for transmission over field-deployed optical fibre. Future optical communication systems will have to use the full available spectral bandwidth and advanced multiplexing and modulation to achieve ultimate data capacity over a fibre link. To realistically test such links, experiments must be performed over "real-world" fibre links. By linking three telecoms rese ....Distributed ultra-fast optical clocks for terabit/s communications. The project aims to enable experiments with full spectrum occupation for transmission over field-deployed optical fibre. Future optical communication systems will have to use the full available spectral bandwidth and advanced multiplexing and modulation to achieve ultimate data capacity over a fibre link. To realistically test such links, experiments must be performed over "real-world" fibre links. By linking three telecoms research laboratories, the project will create a close collaboration optical network that enables this research. Anticipated outcomes are the opportunity to conduct research over field-deployed fibre links and to prototype and test communication technology over real-world links, creating a simplified path to commercialisation.Read moreRead less
Routing shapes of light for the next generation of fibre optic networks. In 2016, the United Nations declared access to the Internet as basic human right. Our communication networks are facing a capacity crunch, which will transform a basic human right for everyone into a privilege for a few. This project aims to avoid a capacity crunch by creating innovative solutions for the next generation of optical fibre communication networks. This project stands to generate new knowledge in photonics, opt ....Routing shapes of light for the next generation of fibre optic networks. In 2016, the United Nations declared access to the Internet as basic human right. Our communication networks are facing a capacity crunch, which will transform a basic human right for everyone into a privilege for a few. This project aims to avoid a capacity crunch by creating innovative solutions for the next generation of optical fibre communication networks. This project stands to generate new knowledge in photonics, optical communication and advanced manufacturing. The expected benefits are new academic collaborations, enhancing Australia’s international standing and economic benefit through commercialisation and training of students for the growing photonics industry in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100062
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Universal Optical Transmitter for rapid prototyping and system emulation. Universal optical transmitter for rapid prototyping and system emulation: This Project proposes an integrated, multi-user facility for the generation of extremely wide-bandwidth optical communication signals that will help to dramatically improve the data-handling capability of optical fibres and improve the energy efficiency of optical communication networks. The project will modulate the input of an advanced optical tran ....Universal Optical Transmitter for rapid prototyping and system emulation. Universal optical transmitter for rapid prototyping and system emulation: This Project proposes an integrated, multi-user facility for the generation of extremely wide-bandwidth optical communication signals that will help to dramatically improve the data-handling capability of optical fibres and improve the energy efficiency of optical communication networks. The project will modulate the input of an advanced optical transmitter with multi-level, multi-phase signals at multi-Gb/s rates to generate 'higher-order' modulation formats at multi- terra bits per second rates including orthogonal frequency-division multiplexing (OFDM), Nyquist-wavelength-division multiplexing (WDM), regular WDM and Optical Time-Division Multiplexing (OTDM). With this transmitter the project will investigate advanced optical communications concepts including 'constellations' of phase and intensity, limitations of nonlinearity in optical fibres, signal regeneration, and all-optical routing.Read moreRead less
Teaching old dogs new tricks: making ordinary glass both guide and modulate light in photonic chips. The continued revolution of telecoms, and other industries, by photonics demands active integrated photonics: chips that can switch, modulate and modify light. Currently this requires problematic materials. This project will innovatively combine breakthroughs in two areas: poling and laser writing, to produce active devices in standard silicate glass chips.
Discovery Early Career Researcher Award - Grant ID: DE160100714
Funder
Australian Research Council
Funding Amount
$354,000.00
Summary
Shaping light – new frontiers in big fast data. This project aims to address the need for new technologies to tackle the bandwidth overload. Because of the basic human desire to communicate and interact, our society has an exponentially growing Internet data demand. The data capacity crunch is imminent. Data demand is rapidly approaching the nonlinear Shannon limit which governs the maximum data capacity of single-mode optical fibres. Bandwidth limitations may have severe implications for societ ....Shaping light – new frontiers in big fast data. This project aims to address the need for new technologies to tackle the bandwidth overload. Because of the basic human desire to communicate and interact, our society has an exponentially growing Internet data demand. The data capacity crunch is imminent. Data demand is rapidly approaching the nonlinear Shannon limit which governs the maximum data capacity of single-mode optical fibres. Bandwidth limitations may have severe implications for society and economy. This project aims to develop chip-scale mode-multiplexers based on innovative 3D integrated photonics and combine them with optical gain to shape light for space-division multiplexed optical communication networks. This is designed to break through the data capacity limit that currently prevents growth in Internet data rates.Read moreRead less
A versatile optical wavelength and mode switching device for future telecommunication networks. This project will develop a next generation switching device for future fibre optical communication networks that will divide their information among several modes of specialty fibre. This device will be a key component for allowing network operators to move to these novel mode-multiplexed networks in order to overcome the looming capacity crunch.
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
Brillouin processing for carrier recovery in optical communications. This project aims to apply Brillouin processing to the development of an innovative, self-tracking optical filter for isolating optical carriers in the coherent receiver of future ultrahigh bit-rate optical communication systems. By recovering a needle-like optical carrier with great precision from a drifting sea of wide-band noise and data channels, the project expects to minimise the effect of optical carrier distortions on t ....Brillouin processing for carrier recovery in optical communications. This project aims to apply Brillouin processing to the development of an innovative, self-tracking optical filter for isolating optical carriers in the coherent receiver of future ultrahigh bit-rate optical communication systems. By recovering a needle-like optical carrier with great precision from a drifting sea of wide-band noise and data channels, the project expects to minimise the effect of optical carrier distortions on the data-carrying signals. The project should advance knowledge in optical signal processing and communications technologies, with outcomes that increase the data-carrying capacity of optical networks. Future telecommunication networks should benefit through improved transmission rates and extended fibre links.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100045
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Coherent Laser Links for Space Applications. Coherent laser links for space applications:
This project seeks equipment to establish a deployable, free-space, coherent laser link to enable Australia’s continued leadership and involvement in large-scale international space projects. It would support optical free-space frequency transfer to expand the capability of the European Space Agency’s Atomic Clock Ensemble in Space mission; tests to validate the inter-satellite interferometry acquisition s ....Coherent Laser Links for Space Applications. Coherent laser links for space applications:
This project seeks equipment to establish a deployable, free-space, coherent laser link to enable Australia’s continued leadership and involvement in large-scale international space projects. It would support optical free-space frequency transfer to expand the capability of the European Space Agency’s Atomic Clock Ensemble in Space mission; tests to validate the inter-satellite interferometry acquisition system for the NASA Gravity Recovery and Climate Experiment follow-on mission; and test-bed development for advanced coherent optical communications systems. Coherent, free-space laser links are an emerging technology for a range of high-impact research fields. The project would enable research relying on precision measurements of time and frequency; advanced inter-satellite laser interferometry, and coherent free-space optical communications. Read moreRead less