Sensing and Communications for Tactical Radio: Mapping the RF Weather. This project investigates sensing, localisation and communication strategies to improve the performance of modern tactical radio networks. Such networks face all of the well-known design challenges of mobile ad-hoc networks (MANETs) but with added complication of a contested and adversarial operating environment. By exploiting the power of radio nodes to sense the radio spectrum, as well as to communicate over it, a distribut ....Sensing and Communications for Tactical Radio: Mapping the RF Weather. This project investigates sensing, localisation and communication strategies to improve the performance of modern tactical radio networks. Such networks face all of the well-known design challenges of mobile ad-hoc networks (MANETs) but with added complication of a contested and adversarial operating environment. By exploiting the power of radio nodes to sense the radio spectrum, as well as to communicate over it, a distributed network of nodes can create a detailed picture of the surrounding radio-frequency (RF) environment: the nodes can work together to map the “RF weather”. In this project we will design advanced sensing and localisation methods to accurately map the RF spectrum, and then exploit this map in communication system design.Read moreRead less
Multiple-input, multiple-output short range optical communications: a broadband solution with virtually unlimited bandwidth. This project will develop new short range communications systems with virtually unlimited bandwidth and combine the speed of optical communications with the convenience of wireless. Applications range from rapid data download to portable devices such as smart phones, to communications within very high speed computers.
Easing the Squeeze: Dynamic and Distributed Resource Allocation with Cognitive Radio. The radio spectrum is a scarce and valuable natural resource which is being squeezed by the rapid growth in wireless communications. Cognitive radios make efficient use of radio spectrum by dynamically reusing frequencies. This requires cognitive radios to sense the local environment and to control the interference caused to existing users of the spectrum. This project will design novel dynamic and distributed ....Easing the Squeeze: Dynamic and Distributed Resource Allocation with Cognitive Radio. The radio spectrum is a scarce and valuable natural resource which is being squeezed by the rapid growth in wireless communications. Cognitive radios make efficient use of radio spectrum by dynamically reusing frequencies. This requires cognitive radios to sense the local environment and to control the interference caused to existing users of the spectrum. This project will design novel dynamic and distributed resource allocation algorithms for cognitive radios in order to significantly improve their performance using techniques from extreme value theory, game theory and mechanism design and large random matrix theory. Read moreRead less
Real-time internet of thing algorithms with performance guarantees. This project aims to provide efficient, distributed resource allocation algorithms that can perform satisfactorily within time limits imposed by real-time systems. Real-time Internet of Things (IoT) devices will play a significant role in future transport technologies, such as autonomous vehicles and smart traffic management, and will place significant demands upon distributed computing systems to provide timely information upda ....Real-time internet of thing algorithms with performance guarantees. This project aims to provide efficient, distributed resource allocation algorithms that can perform satisfactorily within time limits imposed by real-time systems. Real-time Internet of Things (IoT) devices will play a significant role in future transport technologies, such as autonomous vehicles and smart traffic management, and will place significant demands upon distributed computing systems to provide timely information updates. The computing challenge is to provide reliable, accurate and timely information to IoT devices. The outcomes of this project will directly be beneficial to a variety of IoT applications in transportation, autonomous vehicles, and smart cities. The valuable engineering insights and novel algorithms will support industry, government, and practitioners for future real-time IoT design and deployments.Read moreRead less
Control protocols for wireless networks. There is tremendous commercial potential in the development of wireless multi-hop and sensor networks. This project will help realize such networks, with commercial benefits for the network providers, and the customers that use them (low cost networking). Particular outcomes targeted for Australian needs include: 1) protocols allowing advanced telecommunications services to cover greater geographic areas with less infrastructure 2) improved reliability o ....Control protocols for wireless networks. There is tremendous commercial potential in the development of wireless multi-hop and sensor networks. This project will help realize such networks, with commercial benefits for the network providers, and the customers that use them (low cost networking). Particular outcomes targeted for Australian needs include: 1) protocols allowing advanced telecommunications services to cover greater geographic areas with less infrastructure 2) improved reliability of local communication services in remote or rugged areas 3) protocols for sensor networks, allowing remote monitoring and control of many environmental factors. Read moreRead less
Self-coherent detection for data centre. This project aims to explore the architecture of terabit data transport using self-coherent detection that addresses the tight constraints of power, space and cost in data centres. The project expects to create new knowledge in coherent detection based on optical equalisation rather than conventional power-hungry electronic equalisation. Expected outcomes of this project include advanced architecture of polarisation effect equalisers and all-optical equal ....Self-coherent detection for data centre. This project aims to explore the architecture of terabit data transport using self-coherent detection that addresses the tight constraints of power, space and cost in data centres. The project expects to create new knowledge in coherent detection based on optical equalisation rather than conventional power-hungry electronic equalisation. Expected outcomes of this project include advanced architecture of polarisation effect equalisers and all-optical equalisation algorithms as well as enhanced international collaboration with top experts in optical communications. The outcomes will contribute to maintaining Australia’s high reputation in the ICT arena.Read moreRead less
Translucent Optical Networks: Architecture, Design, Operation, and Survivability. Australia is a geographically disperse country. Long-haul optical transport networks are key communication infrastructure between metropolises. Our research aims to discover cost-effective network architecture and planning and operational strategies for optical transport networks, which is beneficial to the deployment and operation of Australian telecommunication networks. In addition, viewing the sparse connectivi ....Translucent Optical Networks: Architecture, Design, Operation, and Survivability. Australia is a geographically disperse country. Long-haul optical transport networks are key communication infrastructure between metropolises. Our research aims to discover cost-effective network architecture and planning and operational strategies for optical transport networks, which is beneficial to the deployment and operation of Australian telecommunication networks. In addition, viewing the sparse connectivity of Australian backbone transport networks, the research on network survivability will provide effective strategies for Australian transport networks to survive any network failures due to natural disasters or terror attacks, thereby providing reliable network services to Australian. Read moreRead less
Architectures and System Technologies for Intelligent Photonic Packet Routers. The photonic packet switching in future all-optical IP centric networks can provide the much needed bandwidth granularity and optimal data transport architectures. Through the adaptation of multi-protocol label switching (MPLS) compatible photonic label switching concepts, photonic packet routers can be easily realised. As part of this project we will develop subsystem technologies for header processing with integrate ....Architectures and System Technologies for Intelligent Photonic Packet Routers. The photonic packet switching in future all-optical IP centric networks can provide the much needed bandwidth granularity and optimal data transport architectures. Through the adaptation of multi-protocol label switching (MPLS) compatible photonic label switching concepts, photonic packet routers can be easily realised. As part of this project we will develop subsystem technologies for header processing with integrated ability to perform optical signal monitoring will be made. Based on these studies, optimal novel intelligent photonic router architectures incorporating these technologies will be developed and demonstrated. Performance optimisation will be carried out through computer modelling.Read moreRead less
Coordinated non-coherent wireless for safe and secure networking. Distributed wireless networks have the potential to serve simultaneous users streaming high-definition video, no dead zones, no interference among users and no reduction in data rate as more users are added. This project will provide a solution to the current limitations of distributed wireless networks aiming at user safety and privacy.
Optical MIMO in Stokes Space: Bridging Coherent and Non-Coherent Detection. Coherent detection aided by high-speed electronic digital signal processors has transformed optical communications within the last decade. However, the high complexity of coherent detection has constrained its application to long-haul transmission. This project aims to propose a novel modulation format based on optical multiple-input multiple-output in Stokes space that can bridge the gap between coherent and non-coheren ....Optical MIMO in Stokes Space: Bridging Coherent and Non-Coherent Detection. Coherent detection aided by high-speed electronic digital signal processors has transformed optical communications within the last decade. However, the high complexity of coherent detection has constrained its application to long-haul transmission. This project aims to propose a novel modulation format based on optical multiple-input multiple-output in Stokes space that can bridge the gap between coherent and non-coherent communication. The proposed research includes design, simulation, and experimental verification of the proposed Stokes vector detection. The successful implementation of the project is expected to provide enabling technologies to future high-speed transport for interconnecting data centres that underpin fast-growing cloud computing.Read moreRead less