Discovery Early Career Researcher Award - Grant ID: DE150100636
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Efficient Coding for Distributed-input Distributed-output Wireless Systems. Inter-user interference is becoming the dominant bottleneck in state-of-the-art wireless networks. This project aims to address this bottleneck problem by studying a new paradigm, referred to as a Distributed-Input Distributed-Output (DIDO) wireless system, which makes the best use of interference. Results from information theory and modern coding techniques will be advanced to develop new design principles and novel ph ....Efficient Coding for Distributed-input Distributed-output Wireless Systems. Inter-user interference is becoming the dominant bottleneck in state-of-the-art wireless networks. This project aims to address this bottleneck problem by studying a new paradigm, referred to as a Distributed-Input Distributed-Output (DIDO) wireless system, which makes the best use of interference. Results from information theory and modern coding techniques will be advanced to develop new design principles and novel physical-layer coding techniques of DIDO systems, leading to substantially improved throughput, reliability, energy efficiency and robustness. This project aims to develop fundamentally enhanced wireless infrastructure with targeted applications in cellular and wireless networks, satellite communications and wireless sensor networks.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101704
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Cloud-based Massive MIMO Design for Future 5G Cellular Networks. As the radio spectrum for cellular services is quickly running out, the next generation cellular networks require some fundamental technology advances to meet the exponentially growing traffic demand. This project aims to produce a cloud-based massive multiple-input-multiple-output cellular system to achieve a substantially higher system capacity without additional spectrum. Key research issues will be addressed by developing novel ....Cloud-based Massive MIMO Design for Future 5G Cellular Networks. As the radio spectrum for cellular services is quickly running out, the next generation cellular networks require some fundamental technology advances to meet the exponentially growing traffic demand. This project aims to produce a cloud-based massive multiple-input-multiple-output cellular system to achieve a substantially higher system capacity without additional spectrum. Key research issues will be addressed by developing novel interference suppression techniques based on joint signal processing and cloud-based resource allocations. The project aims to leverage recent advances in cloud-based optimisation and utilise interference cancellation to provide fundamentally new approaches in increasing the capacity of cellular systems.Read moreRead less
Efficient signal transmission techniques for large scale antenna systems. This project aims to design efficient signal transmission techniques for large scale antenna wireless systems that can significantly improve network capacity and radio spectrum efficiency. Large scale antenna arrays deployed in cellular networks is a promising technique to accommodate the dramatically increasing data demands for next generation wireless communications. The intended outcome of the project will bring revolut ....Efficient signal transmission techniques for large scale antenna systems. This project aims to design efficient signal transmission techniques for large scale antenna wireless systems that can significantly improve network capacity and radio spectrum efficiency. Large scale antenna arrays deployed in cellular networks is a promising technique to accommodate the dramatically increasing data demands for next generation wireless communications. The intended outcome of the project will bring revolutionary change in mobile wireless communications and benefit billions of people in the world. It will significantly lift productivity and economic growth in Australia.Read moreRead less
Inter-cell interference modelling and control in future cellular systems. Small cells and frequency reuse are the key concepts in increasing the capacity of wireless cellular networks. However, the deployment of dense cells increases interference and limits the network capacity. This project will deliver novel interference control methods, capable of improving the spectral and energy efficiency in cellular networks.
Overcoming the wireless throughput bottleneck: new heterogeneous architectures and algorithms for high data rate mobile broadband. Mobile communication networks are facing a rapid increase in broadband data with traffic forecast to increase by 18 times over the next five years. This project will create novel techniques for the design of a new wireless multi-layered network architecture that will scale to meet this demand whilst minimising the energy footprint of the network.
Low-Complexity Capacity-Scalable Multiple Antenna Wireless Communications. The project aims to develop innovative solutions for low-complexity, capacity-scalable multiple antenna wireless communications, in order to meet future data rate requirements whilst maintaining a practical system at a sustainable cost. By leveraging delay-Doppler domain channel properties and geometric reciprocity, pragmatic transceiver technologies and innovative delay-Doppler domain signal processing algorithms for cha ....Low-Complexity Capacity-Scalable Multiple Antenna Wireless Communications. The project aims to develop innovative solutions for low-complexity, capacity-scalable multiple antenna wireless communications, in order to meet future data rate requirements whilst maintaining a practical system at a sustainable cost. By leveraging delay-Doppler domain channel properties and geometric reciprocity, pragmatic transceiver technologies and innovative delay-Doppler domain signal processing algorithms for channel prediction and multi-user transmissions will be developed. The outcomes of the project are expected to significantly improve users' data rates with low system complexity and reduced signalling overhead for future wireless communications.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.
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