Design of network coding schemes for the next generation of wireless cellular systems. Network coding schemes are expected to become one of the key radio technologies and could have a far-reaching impact on the Australian economy. The proposed program will contribute to theory and development of network coding techniques and their application in future wireless networks.
What to do about WiFi Congestion? New methods for dense, wireless networks. This project aims to design and analyse new protocols for (wireless) WiFi networks. The demand on current WiFi networks is escalating at a tremendous rate. WiFi uses the unlicensed radio spectrum, so innovation can occur more easily over WiFi than over carrier-owned networks. WiFi also provides data offloading from severely congested cellular wireless networks. Unfortunately, the current WiFi multiple access protocols we ....What to do about WiFi Congestion? New methods for dense, wireless networks. This project aims to design and analyse new protocols for (wireless) WiFi networks. The demand on current WiFi networks is escalating at a tremendous rate. WiFi uses the unlicensed radio spectrum, so innovation can occur more easily over WiFi than over carrier-owned networks. WiFi also provides data offloading from severely congested cellular wireless networks. Unfortunately, the current WiFi multiple access protocols were not designed to handle closely packed WiFi networks and the resulting interference. This project takes a novel approach to develop algorithms that are much more robust to interference, and which use simple, distributed mechanisms to feed channel state information back from the receiver to the transmitter to maximise performance.Read moreRead less
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
Information-theoretic capacity of outdoor mm-wave wireless communications. This project aims to fundamentally characterise the practical information carrying capacity of future mm-wave wireless communication networks. The mm-wave spectrum offers 10-100 times the bandwidth used by current mobile networks, but comes with many challenges. An information theoretic model will be developed incorporating state of the art mm-wave channel models, and practical engineering implementation constraints. The ....Information-theoretic capacity of outdoor mm-wave wireless communications. This project aims to fundamentally characterise the practical information carrying capacity of future mm-wave wireless communication networks. The mm-wave spectrum offers 10-100 times the bandwidth used by current mobile networks, but comes with many challenges. An information theoretic model will be developed incorporating state of the art mm-wave channel models, and practical engineering implementation constraints. The expected outcome will be new network designs and data transmission technologies that unlock the spectrum by enabling secure outdoor mobile cellular deployments with wide-spread coverage. This will support vastly greater traffic densities and data rates.Read moreRead less
Design of rateless network coded future wireless cellular systems. High speed future communication networks are critical tools for achieving economic sustainability and could have a far-reaching impact on the Australian economy. The proposed program will have the potential to transform future wireless communication systems and bring considerable technical, economic and environmental benefits.
Agile and Efficient Machine to Machine Communication Systems. The project plans to deliver building blocks for designing future machine-to-machine (M2M) wireless access networks with a wide range of new applications. M2M communications have emerged as a new communication paradigm and are likely to become a dominant form of future communications. The project aims to develop novel communications techniques that are tailored to unique M2M network characteristics and requirements and demonstrate the ....Agile and Efficient Machine to Machine Communication Systems. The project plans to deliver building blocks for designing future machine-to-machine (M2M) wireless access networks with a wide range of new applications. M2M communications have emerged as a new communication paradigm and are likely to become a dominant form of future communications. The project aims to develop novel communications techniques that are tailored to unique M2M network characteristics and requirements and demonstrate the proposed algorithms in practical systems. The outcomes are intended to contribute to the modernisation and transformation of critical infrastructures into smart systems, delivering more reliable, efficient and cost-effective services.Read moreRead less
Compressed network sharing for large-scale distributed systems. The project will make the critical theoretical advances to enable the building of large-scale machine-to-machine communications systems. This will be the essential precursor to technologies for constructing Australia’s intelligent infrastructure and smart cities.
New channel estimation, tracking and equalization algorithms for real-time high-speed underwater acoustic communication systems. High-speed underwater communication is vitally important for Australian offshore oil and gas industries, marine commercial operations, and defence applications. However, due to the challenges posed by the harsh underwater channel, current underwater communication systems have significant limitations on data rate and bit-error-rate for many applications and environments ....New channel estimation, tracking and equalization algorithms for real-time high-speed underwater acoustic communication systems. High-speed underwater communication is vitally important for Australian offshore oil and gas industries, marine commercial operations, and defence applications. However, due to the challenges posed by the harsh underwater channel, current underwater communication systems have significant limitations on data rate and bit-error-rate for many applications and environments. This project aims to develop a real-time signal processing platform for reliable high-speed communication through the extremely bandlimited and reverberant underwater acoustic channel. New channel estimation, tracking and equalisation algorithms developed in this project will significantly enhance the capacity of underwater communication systems.Read moreRead less
Increasing the range and rate of underwater acoustic communication systems using multi-hop relay. Australia has a very long coastline, thus it is vitally important for Australia to efficiently explore and exploit the rich resources in the ocean. This project develops novel communication technologies for long-range and high-rate underwater acoustic communications that are crucial to Australian ocean-related industries and defence applications.
Gigabit wireless multiple access at E-band. This project will develop the theoretical advances that will lead to the creation of gigabit wireless multiple access networks, with data rates at least two orders of magnitude faster than current wireless networks. This will enable cost-effective 'last mile' links to the national broadband network in densely populated urban areas and in rural and regional Australia.