Discovery Early Career Researcher Award - Grant ID: DE170101203
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Multi-functional antenna arrays for secure and reliable wireless systems. This project aims to develop and validate the fundamental theory and engineering techniques for fully reconfigurable antenna arrays. Multi-functional antennae deliver highly-secure and reliable wireless communications for Australia’s digital economy. Such an antenna array, a critical component of wireless multi-functional systems, can provide full flexibilities of the frequency, polarisation and radiation pattern to satisf ....Multi-functional antenna arrays for secure and reliable wireless systems. This project aims to develop and validate the fundamental theory and engineering techniques for fully reconfigurable antenna arrays. Multi-functional antennae deliver highly-secure and reliable wireless communications for Australia’s digital economy. Such an antenna array, a critical component of wireless multi-functional systems, can provide full flexibilities of the frequency, polarisation and radiation pattern to satisfy the systems’ different requirements. This project is expected to advance the scientific knowledge of several frontiers of antenna research and enhance spectrum usage efficiency, highly-secure wireless communications and compact and reliable military wireless platforms, thus benefiting Australian industry, society and national defence.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100651
Funder
Australian Research Council
Funding Amount
$414,000.00
Summary
Intelligent Backscatter Communications for Green and Secure IoT Networks . This project aims to develop novel technologies empowered by intelligent radio wave backscatter to address the significant problem of connecting a very large number of wireless devices with low energy consumption and limited communication channels for future Internet-of-Things (IoT) networks. This project expects to advance knowledge in the area of green communications by utilising ambient backscatter, a breakthrough wire ....Intelligent Backscatter Communications for Green and Secure IoT Networks . This project aims to develop novel technologies empowered by intelligent radio wave backscatter to address the significant problem of connecting a very large number of wireless devices with low energy consumption and limited communication channels for future Internet-of-Things (IoT) networks. This project expects to advance knowledge in the area of green communications by utilising ambient backscatter, a breakthrough wireless communications technology. This will significantly reduce energy costs, enhance spectrum usage efficiency, and improve communication security thus greatly benefiting Australian industry, society and economy. Expected outcomes of the project include key technologies that promote the development of future IoT networks.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100116
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
100 Gbit to 1 Terabit per second optical communication test bed facility. This facility will develop and demonstrate novel optical technologies that will underpin the generation and transmission of a higher-speed Ethernet at 100 Gb/s to 1Terabit/s, and will lead to better broadband and more energy efficient internet. At the foundation of this research will be a test bed with multiple signal sources at data rates above 50 Gbaud.
Discovery Early Career Researcher Award - Grant ID: DE150101535
Funder
Australian Research Council
Funding Amount
$357,000.00
Summary
Smart radio-frequency filter in a tuneable optical circuit. A massive technology gap of high quality tuneable filters in the microwave (1-100 GHz) frequency range is impeding advances towards fully-reconfigurable wireless systems. This project aims to address this limitation and to deliver the world's first reconfigurable microwave filter with unprecedented tuning range, resolution, and selectivity using integrated microwave photonics technology. The project aims to produce the critical filter t ....Smart radio-frequency filter in a tuneable optical circuit. A massive technology gap of high quality tuneable filters in the microwave (1-100 GHz) frequency range is impeding advances towards fully-reconfigurable wireless systems. This project aims to address this limitation and to deliver the world's first reconfigurable microwave filter with unprecedented tuning range, resolution, and selectivity using integrated microwave photonics technology. The project aims to produce the critical filter technology for advanced radio spectrum management and efficient bandwidth utilisation. The project will endeavour to have a profound impact on virtually all high bandwidth microwave systems in key sectors such as wireless communications, defence, and radio astronomy.Read moreRead less
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
Integration of broadband microwave photonic frequency convertors. This project aims to develop microwave photonic processors with increased bandwidth and unprecedented radio frequency signal processing. The new technology will enhance radar systems and electronic-warfare capabilities, and allow more flexible delivery of bandwidth for mobile communication systems. Benefits for Australian end-users and industry include improved surveillance for defence and revenue growth in companies working with ....Integration of broadband microwave photonic frequency convertors. This project aims to develop microwave photonic processors with increased bandwidth and unprecedented radio frequency signal processing. The new technology will enhance radar systems and electronic-warfare capabilities, and allow more flexible delivery of bandwidth for mobile communication systems. Benefits for Australian end-users and industry include improved surveillance for defence and revenue growth in companies working with the Australian defence forces.Read moreRead less
Algorithms and data structures to support automated analysis of trajectory data. The emergence of a variety of tracking devices, surveillance systems and even electronic transaction and phone networks has resulted in the production of large amounts of positional information for vehicles, people and animals. The aim of the project is to develop tools that support automated analysis of such data sets.