Optical wireless frontier: Design challenges of multi gigabit wireless. This project aims to improve the coverage, mobile access, miniaturisation, bandwidth and networking of optical wireless. As connected machines become the primary consumers of the Internet, technologies for wirelessly connecting devices, processors, storage and display devices at very high speeds become necessary for mission critical services and applications. Gigabit wireless access needs to overcome shortages in the radio-f ....Optical wireless frontier: Design challenges of multi gigabit wireless. This project aims to improve the coverage, mobile access, miniaturisation, bandwidth and networking of optical wireless. As connected machines become the primary consumers of the Internet, technologies for wirelessly connecting devices, processors, storage and display devices at very high speeds become necessary for mission critical services and applications. Gigabit wireless access needs to overcome shortages in the radio-frequency spectrum and provide scalable bandwidth and wider coverage. Optical wireless transmission is a real alternative to current wireless systems because its connection speed of tens of gigabits/second means it can work efficiently with wired optical networking technologies. This project is expected to lead to optical wireless technology.Read moreRead less
High-density mobile fronthaul optical interconnects using few-mode fibers. This project aims to develop a prototype of high-density optical interconnects for mobile fronthaul systems using few-mode transmission techniques. This is required to meet the high bandwidth demand from 5G mobile standard, which is to be rolled out worldwide in the near future. The project expects to advance knowledge of space-division-multiplexing techniques using cost-effective direct detection. The methodologies and t ....High-density mobile fronthaul optical interconnects using few-mode fibers. This project aims to develop a prototype of high-density optical interconnects for mobile fronthaul systems using few-mode transmission techniques. This is required to meet the high bandwidth demand from 5G mobile standard, which is to be rolled out worldwide in the near future. The project expects to advance knowledge of space-division-multiplexing techniques using cost-effective direct detection. The methodologies and technologies developed through this project will enhance the competitiveness of the Australian’s telecommunication sector, especially on the deployment of 5G services to the broader community. This technology will be critical to Australia’s digital economy, from supporting virtual reality to autonomous driving and will provide significant benefits to the Australian optical communication industry.
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Discovery Early Career Researcher Award - Grant ID: DE170100585
Funder
Australian Research Council
Funding Amount
$365,000.00
Summary
On-chip generation and processing of high-power multi-GHz frequency combs. The project aims to deliver a chip-scale stable optical frequency comb technology with high-power and multi-GHz frequency spacing. The lack of this technology has prevented fundamental advances in wide-ranging applications that require high signal-to-noise-ratio (SNR) combs. The project seeks to demonstrate combs using waveguide laser technology and to integrate it with a reconfigurable optical filter to select and proces ....On-chip generation and processing of high-power multi-GHz frequency combs. The project aims to deliver a chip-scale stable optical frequency comb technology with high-power and multi-GHz frequency spacing. The lack of this technology has prevented fundamental advances in wide-ranging applications that require high signal-to-noise-ratio (SNR) combs. The project seeks to demonstrate combs using waveguide laser technology and to integrate it with a reconfigurable optical filter to select and process individual comb lines. Key advantages of this technology, including high SNR, reconfigurability, high stability, small footprint and low-cost, are expected to improve astronomy’s ability to detect Earth-like planets, telecommunications to increase the overall internet capacity, and global positioning systems (GPS).Read moreRead less
Breaking the glass ceiling: silicon-nitride (SiN) and doped silica glass for ultra high speed Complementary metal-oxide-semiconductor (CMOS) compatible optical processing and measurement chips. The global internet demands for energy and technology will soon be unsustainable. This project will pioneer faster, cheaper, far smaller, and more energy efficient optical signal processing and measurement chips compatible with silicon CMOS technology, for applications in telecommunications, silicon integ ....Breaking the glass ceiling: silicon-nitride (SiN) and doped silica glass for ultra high speed Complementary metal-oxide-semiconductor (CMOS) compatible optical processing and measurement chips. The global internet demands for energy and technology will soon be unsustainable. This project will pioneer faster, cheaper, far smaller, and more energy efficient optical signal processing and measurement chips compatible with silicon CMOS technology, for applications in telecommunications, silicon integrated circuits, and fundamental science.Read moreRead less