Novel Multistage and Iterative Receivers for Wireless Communication Systems. The project is set up to develop novel detection techniques with the aim of improving the reliability and capacity in a range of wireless telecommunications services. Potential applications of the project outcomes are in cellular mobile, wireless LANs and mobile computing.
Adaptive Turbo Receivers for Mobile Data Communications. Next generation mobile networks will be required to offer high data-rate high mobility communications, in addition to current voice services. This project will determine the bounds of achievable performance of such networks by developing and analysing new optimal and near optimal adaptive receivers. In particular we will extend a revolutionary new technique called turbo processing, to achieve joint equalization and decoding with unknown ....Adaptive Turbo Receivers for Mobile Data Communications. Next generation mobile networks will be required to offer high data-rate high mobility communications, in addition to current voice services. This project will determine the bounds of achievable performance of such networks by developing and analysing new optimal and near optimal adaptive receivers. In particular we will extend a revolutionary new technique called turbo processing, to achieve joint equalization and decoding with unknown rapidly time varying channels. The overall aim is to dramatically improve mobility and throughput of wireless data communication systems.Read moreRead less
Space-Time Coding and Receiver Structures for High Speed Wireless Communications. The aims of the project are to to devise space-time coding techniques and cost effective receiver structures for applications in future wireless data networks. We expect that new space-time codes would enable an increase in spectral efficiency by two orders of magnitude compared with the existing systems and allow the introduction of advanced multimedia services.
Microwave Antennas based on Metamaterials. This project concerns one of the most exciting and dynamic areas of research at present. Metamaterials have tremendous potential, with the promise of multitudinous applications in microwave, optical and optoelectronic fields. This project will contribute towards the ARC priority goal on advanced materials and frontier technologies by (a) developing new synthesized materials which have special properties not found in nature, and (b) developing new techn ....Microwave Antennas based on Metamaterials. This project concerns one of the most exciting and dynamic areas of research at present. Metamaterials have tremendous potential, with the promise of multitudinous applications in microwave, optical and optoelectronic fields. This project will contribute towards the ARC priority goal on advanced materials and frontier technologies by (a) developing new synthesized materials which have special properties not found in nature, and (b) developing new technologies to deliver practical benefits for communication systems users by exploiting these materials. Other benefits for Australia include intellectual property and patent outcomes, which may help Australia to become a leader in metamaterial-based technologies.Read moreRead less
Construction methods and analysis tools for repeat-accumulate error correction codes. Error correction codes play an integral role in digital communications systems, enabling technologies such as compact-disk players, hard-disk drives, high-speed modems, digital audio broadcasting and deep-space communications. This project develops the techniques which underlie the success of next-generation error correction technologies and thus addresses an important and fundamental problem in the area of inf ....Construction methods and analysis tools for repeat-accumulate error correction codes. Error correction codes play an integral role in digital communications systems, enabling technologies such as compact-disk players, hard-disk drives, high-speed modems, digital audio broadcasting and deep-space communications. This project develops the techniques which underlie the success of next-generation error correction technologies and thus addresses an important and fundamental problem in the area of information and communications technology (ICT). The nature of the project presents significant potential for project outcomes to be beneficial to the Australian telecommunications industry in a wide range of application areas including wireless networks, mobile communications, and data storage.
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Optimising Cooperation in Multiterminal Wireless Networks. With more and more of our communications networks becoming wireless, new technologies are required to ensure optimal use of limited resources. This project develops and optimises cooperation for multiterminal wireless networks to increase the transmission rate and / or lower the power consumption of wireless networks. Benefits of this research are efficient deployment and operation of high-speed wireless networks such as broadband Inter ....Optimising Cooperation in Multiterminal Wireless Networks. With more and more of our communications networks becoming wireless, new technologies are required to ensure optimal use of limited resources. This project develops and optimises cooperation for multiterminal wireless networks to increase the transmission rate and / or lower the power consumption of wireless networks. Benefits of this research are efficient deployment and operation of high-speed wireless networks such as broadband Internet and digital television, and improved lower-power wireless sensor networks for applications such as remote monitoring bushfire early warning systems.Read moreRead less
Iterative coding for next generation networks. The demands on next generation telecommunication networks can be extrapolated from the increasing use of Voice Over IP (e.g., Skype), real-time streaming media (e.g., live sporting events), and downloaded movies (e.g., the iTunes Music Store). In this data-rich environment, it is necessary to utilise the network itself intelligently. This project draws together ideas from error correction and network coding to provide the technologies that will un ....Iterative coding for next generation networks. The demands on next generation telecommunication networks can be extrapolated from the increasing use of Voice Over IP (e.g., Skype), real-time streaming media (e.g., live sporting events), and downloaded movies (e.g., the iTunes Music Store). In this data-rich environment, it is necessary to utilise the network itself intelligently. This project draws together ideas from error correction and network coding to provide the technologies that will underpin next generation communication networks. With a focus on implementable technologies, this project presents significant potential for project outcomes to impact the Australian information economy, spawning new businesses, transforming established industries, and creating new jobs. Read moreRead less
Structured low-density parity-check codes for next-generation digital communications. The promise of essentially error-free information transmission is a cornerstone of digital communications. Next-generation applications demand increasingly effective error correction, yet traditional systems fall well short of fundamental capacity limits established some fifty years ago. Exciting breakthroughs in the mid-1990s delivered capacity-approaching codes on graphs employing iterative decoding algorithm ....Structured low-density parity-check codes for next-generation digital communications. The promise of essentially error-free information transmission is a cornerstone of digital communications. Next-generation applications demand increasingly effective error correction, yet traditional systems fall well short of fundamental capacity limits established some fifty years ago. Exciting breakthroughs in the mid-1990s delivered capacity-approaching codes on graphs employing iterative decoding algorithms, including low-density parity-check (LDPC) codes. This project applies techniques from discrete mathematics to design structured LDPC coding schemes for widespread implementation. Outcomes of this research will be new LDPC codes, encoding algorithms and analysis techniques for applications including wireless networks, data storage and Internet communications.Read moreRead less
Efficient Signal Transmission Techniques for Future Wireless Communications Systems. The project aims at developing efficient signal transmission techniques that enable advanced telecommunication services to achieve high quality and cover greater geographic areas with low cost and minimal infrastructure. The outcomes of the project will enable high performance, high data rate and cost-effective wireless communications in Australia. The outcomes can be directly applied to current and future wirel ....Efficient Signal Transmission Techniques for Future Wireless Communications Systems. The project aims at developing efficient signal transmission techniques that enable advanced telecommunication services to achieve high quality and cover greater geographic areas with low cost and minimal infrastructure. The outcomes of the project will enable high performance, high data rate and cost-effective wireless communications in Australia. The outcomes can be directly applied to current and future wireless LAN, cellular mobile networks, WiMax systems, WiFi and other wireless networks. In addition, it will support and enhance the social and economic benefit of wireless access to broadband networks in rural and regional Australia.Read moreRead less
Architecture-based Open Network Management Systems for Next Generation Telecommunications. We aim to develop an open, policy-based architecture for the management of next generation telecommunications networks. It is expected that a comprehensive Open Architecture-based Telecommunications Management Network (AuTuMN) framework could be put in place to manage the network based on centralised policies and roles rather than having to handle individual users and elements. Significantly, the scient ....Architecture-based Open Network Management Systems for Next Generation Telecommunications. We aim to develop an open, policy-based architecture for the management of next generation telecommunications networks. It is expected that a comprehensive Open Architecture-based Telecommunications Management Network (AuTuMN) framework could be put in place to manage the network based on centralised policies and roles rather than having to handle individual users and elements. Significantly, the scientific knowledge of open systems and network management systems for next generation networks will be extended.Read moreRead less