Physical layer security techniques for multiuser wireless networks. This project will develop innovative new security techniques for wireless networks. The novel techniques we develop will exploit the natural variability of wireless communication channels in order to deliver much-enhanced data security to a whole range of applications over the mobile internet.
Massive Multiple-input Multiple-output technique for 5G wireless networks. This project aims to develop innovative large-scale antenna array communication techniques to improve the energy efficiency and spectrum efficiency of wireless data networks. The proposed massive multiple-input multiple-output (MIMO) designs would exploit extremely large antenna apertures with very sharp radio beams to improve the throughput of the state-of-the-art MIMO by an order of magnitude. The project plans to devis ....Massive Multiple-input Multiple-output technique for 5G wireless networks. This project aims to develop innovative large-scale antenna array communication techniques to improve the energy efficiency and spectrum efficiency of wireless data networks. The proposed massive multiple-input multiple-output (MIMO) designs would exploit extremely large antenna apertures with very sharp radio beams to improve the throughput of the state-of-the-art MIMO by an order of magnitude. The project plans to devise novel and pragmatic signal processing and coding approaches for very large antenna arrays for this new type of wireless infrastructure. It is expected that the project outcomes would dramatically increase the data speed for 5G mobile and future WiFi networks and benefit users through pervasive wireless broadband access.Read moreRead less
Spectrum efficient wireless technologies for 5G cellular networks. Spectrum efficient wireless technologies for 5G cellular networks. This project aims to design future generation wireless network technologies for 5G cellular networks, whose new and advanced spectrum and interference management technologies can improve the network capacity and radio spectrum efficiency. This is pressing, as the current fourth generation (4G) cellular communications technology will soon not be able to meet increa ....Spectrum efficient wireless technologies for 5G cellular networks. Spectrum efficient wireless technologies for 5G cellular networks. This project aims to design future generation wireless network technologies for 5G cellular networks, whose new and advanced spectrum and interference management technologies can improve the network capacity and radio spectrum efficiency. This is pressing, as the current fourth generation (4G) cellular communications technology will soon not be able to meet increasing demands for high-speed wireless access. This project is intended to bring revolutionary change in the mobile wireless communications and benefit billions of people worldwide.Read moreRead less
Optimum cross-layer design in wireless communication systems with channel uncertainty. For wireless communications to be part of Australia's information delivery infrastructure, including the National Broadband Network, requires improvements in reliability, speed and cost effectiveness over current technologies. The assembled world class research team has the objective to develop advanced design techniques to meet this challenge.
Efficient cross-layer coding techniques for wireless networks. This project is proposed to develop novel wireless communication/networking design theory and practical strategies based on the emerging network coding technique. The expected outcomes can be used to substantially increase network throughput and reliability of future wireless services, such as wireless Internet and mobile broadcasting.
Novel Techniques for Uncoordinated Massive Access in the Internet of Things. The IoT (internet of things) is the backbone of intelligent transportation, healthcare, energy and smart home systems. To accommodate the exponentially increasing number of IoT devices, a dramatic paradigm shift towards non-orthogonal uncoordinated (grant-free) massive access is underway, where devices transmit data opportunistically over shared channel resources. This project aims to develop new receivers for such unc ....Novel Techniques for Uncoordinated Massive Access in the Internet of Things. The IoT (internet of things) is the backbone of intelligent transportation, healthcare, energy and smart home systems. To accommodate the exponentially increasing number of IoT devices, a dramatic paradigm shift towards non-orthogonal uncoordinated (grant-free) massive access is underway, where devices transmit data opportunistically over shared channel resources. This project aims to develop new receivers for such uncoordinated massive access, where the receivers will be trained to identify transmitting devices, recover their data, and resolve any collisions. These outcomes are expected to emerge as a game changer in IoT communications, benefiting national and international industry to meet future telecommunications needs for the IoT.Read moreRead less
Orthogonal Time Frequency Space Modulation for Future Mobile Communications. Future wireless systems need to support high-mobility services, including self-driving autonomous cars, in-vehicle infotainment, and communications onboard aircraft. This project proposes to develop novel orthogonal time frequency space (OTFS) communications theories and pragmatic transceiver techniques, aiming to substantially improve data rates, reliability, and robustness of future high-mobility communications. Innov ....Orthogonal Time Frequency Space Modulation for Future Mobile Communications. Future wireless systems need to support high-mobility services, including self-driving autonomous cars, in-vehicle infotainment, and communications onboard aircraft. This project proposes to develop novel orthogonal time frequency space (OTFS) communications theories and pragmatic transceiver techniques, aiming to substantially improve data rates, reliability, and robustness of future high-mobility communications. Innovative transceiver techniques, signal processing algorithms for channel estimation and detection, and efficient coding approaches will be devised for OTFS systems. The project outcomes are expected to advance the capabilities of high-mobility communications and provide significant benefits for users and network providers.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100246
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Achieving high-speed wireless communication networks through joint channel and network coding. This project will develop new coding techniques to increase the data transmission speed of wireless networks. The success of this project will enable a smooth migration from wired to wireless networks for applications that require high data speed like broadband Internet, high-definition video streaming, and health-monitoring system.
Millimetre wave communications for mobile broadband systems. This project aims to develop innovative millimetre wave (mmWave) communication theories and techniques, in order to significantly improve the data rate and network capacity for mobile broadband. Pragmatic transceiver designs, channel estimation algorithms, and network optimisation tools will be developed to quantify the potential of this promising wireless infrastructure. The technologies are designed to exploit the abundant mmWave spe ....Millimetre wave communications for mobile broadband systems. This project aims to develop innovative millimetre wave (mmWave) communication theories and techniques, in order to significantly improve the data rate and network capacity for mobile broadband. Pragmatic transceiver designs, channel estimation algorithms, and network optimisation tools will be developed to quantify the potential of this promising wireless infrastructure. The technologies are designed to exploit the abundant mmWave spectrum and complement the state-of-the-art cellular systems to fulfil the formidable demand for ultra-fast data services. The project outcomes are expected to increase mobile broadband speed by an order of magnitude which can benefit end-user experience and open up new opportunities for network providers.Read moreRead less
Massive connectivity and low latency machine-to-machine communications. Massive connectivity and low latency machine-to-machine communications. This project aims to develop communications protocols and algorithms to enable energy-efficient, reliable and low latency machine-to-machine (M2M) networks, connecting a massive number of heterogeneous machine type devices. M2M communications are key to unlocking the Internet of Things’s potential to improve economic productivity and life quality. This p ....Massive connectivity and low latency machine-to-machine communications. Massive connectivity and low latency machine-to-machine communications. This project aims to develop communications protocols and algorithms to enable energy-efficient, reliable and low latency machine-to-machine (M2M) networks, connecting a massive number of heterogeneous machine type devices. M2M communications are key to unlocking the Internet of Things’s potential to improve economic productivity and life quality. This project will develop new theories and devise a proof-of-concept M2M test-bed to evaluate and verify the proposed technologies. The intended outcomes of the project are to contribute to the global standardisation of M2M networks and the new type of world-class wireless infrastructure, as an integral part of the emerging digital society.Read moreRead less