An Integrated Ground Deformation Monitoring System Based on the Integration of InSAR, GPS and GIS Technologies. Interferometric Synthetic Aperture Radar (InSAR) can be used to monitor ground deformation at high spatial resolution. When integrated with Global Positioning Systems (GPS) so that atmospheric disturbance in InSAR result can be corrected, deformation can be resolved at sub-centimetre accuracy. The corrected InSAR result can be exported as a data layer into Geographic Information System ....An Integrated Ground Deformation Monitoring System Based on the Integration of InSAR, GPS and GIS Technologies. Interferometric Synthetic Aperture Radar (InSAR) can be used to monitor ground deformation at high spatial resolution. When integrated with Global Positioning Systems (GPS) so that atmospheric disturbance in InSAR result can be corrected, deformation can be resolved at sub-centimetre accuracy. The corrected InSAR result can be exported as a data layer into Geographic Information Systems (GIS) for further analysis. In collaboration with Hong Kong Polytechnic University researchers, the integrated InSAR-GPS-GIS system will be tested in both Hong Kong and Australia. The expected outcomes include a suite of algorithms and software tools capable of operational, cost-effective ground deformation monitoring.Read moreRead less
Third Generation of Positioning System for Underground Mine Environments. This project aims to research a robust high accuracy positioning system for underground mining environments to improve worker safety and mine efficiency. Positioning in underground mining environments is a key requirement in ensuring the safety of mine workers. It is also a critical technological capability in resolving mine productivity bottlenecks. Australia is one of the largest mining nations and is a leader in mining- ....Third Generation of Positioning System for Underground Mine Environments. This project aims to research a robust high accuracy positioning system for underground mining environments to improve worker safety and mine efficiency. Positioning in underground mining environments is a key requirement in ensuring the safety of mine workers. It is also a critical technological capability in resolving mine productivity bottlenecks. Australia is one of the largest mining nations and is a leader in mining-related research and development and this project intends to support the growth of the valuable mining sector by addressing a significant engineering challenge.Read moreRead less
Sensor Integration for Low-Cost Robust Machine Automation. Machine automation (MA) radically improves efficiency of mining and construction operataions. When used for farming, it makes Australia more competitive with subsidised competitors in Europe and USA. In one case, a 50% reduction in tractor fleet resulted when night plowing was made possible using MA techniques. The systems developed in this project will make MA far more attractive to Australian agriculture, mining and construction indust ....Sensor Integration for Low-Cost Robust Machine Automation. Machine automation (MA) radically improves efficiency of mining and construction operataions. When used for farming, it makes Australia more competitive with subsidised competitors in Europe and USA. In one case, a 50% reduction in tractor fleet resulted when night plowing was made possible using MA techniques. The systems developed in this project will make MA far more attractive to Australian agriculture, mining and construction industries, by making it more robust and less susceptible to difficult conditions, such as under trees.Read moreRead less
Integrated GPS and interferometric SAR techniques for ground subsidence monitoring. The Global Positioning System (GPS) is commonly used for measuring ground subsidence due to underground mining and similar activities. However, GPS techniques cannot easily survey a dense enough grid of points to monitor subsidence across a wide area. This project aims to densify the GPS field measurements with the interferometric processing of Synthetic Aperture Radar (SAR) images. The outcomes of this research ....Integrated GPS and interferometric SAR techniques for ground subsidence monitoring. The Global Positioning System (GPS) is commonly used for measuring ground subsidence due to underground mining and similar activities. However, GPS techniques cannot easily survey a dense enough grid of points to monitor subsidence across a wide area. This project aims to densify the GPS field measurements with the interferometric processing of Synthetic Aperture Radar (SAR) images. The outcomes of this research include optimal integration models, operational software systems and quality-control measures. A test area south of Sydney, where subsidence caused by underground coal mining is having significant detrimental effect on surface infrastructure, will be monitored over a three-year period.Read moreRead less
Integration of GPS/Pseudolites/INS to Geo-Reference Airborne Surveying and Mapping Sensors. This project aims to develop and test an innovative geo-referencing system for airborne surveying and mapping sensors. The proposed new system will be based on the deep integration of measurements from Global Positioning System (GPS), Inertial Navigation Systems (INS), and Pseudo-satellites (Pseudolites). This new system design can significantly improve the accuracy and reliability of the existing syste ....Integration of GPS/Pseudolites/INS to Geo-Reference Airborne Surveying and Mapping Sensors. This project aims to develop and test an innovative geo-referencing system for airborne surveying and mapping sensors. The proposed new system will be based on the deep integration of measurements from Global Positioning System (GPS), Inertial Navigation Systems (INS), and Pseudo-satellites (Pseudolites). This new system design can significantly improve the accuracy and reliability of the existing systems. This research will include theoretical analysis, algorithm development, system implementation, and performance evaluation, towards an operational geo-referencing system addressing ever-increasing demand for rapid acquisition of high quality spatial data from airborne sensors.Read moreRead less
An Augmented-GPS Software Receiver for Indoor/Outdoor Positioning. This research student project will focus on the technical design of a personal positioning device, based on the measurement of a combination of GPS satellite and ground-transmitted signals. The design will incorporate Australian innovations in high-sensitivity GPS receivers, and 'pseudo-satellite' technologies. The integration of the GPS and 'pseudo-satellite' technologies will be carried out within a 'software receiver', which ....An Augmented-GPS Software Receiver for Indoor/Outdoor Positioning. This research student project will focus on the technical design of a personal positioning device, based on the measurement of a combination of GPS satellite and ground-transmitted signals. The design will incorporate Australian innovations in high-sensitivity GPS receivers, and 'pseudo-satellite' technologies. The integration of the GPS and 'pseudo-satellite' technologies will be carried out within a 'software receiver', which offers the opportunity of flexibility in the design of signal processing and navigation algorithms. The receiver design is intended to address the critical challenges for a low-cost, ubiquitous, high accuracy positioning device for a variety of indoor and outdoor consumer applications.Read moreRead less
Trustworthy positioning for intelligent transport systems. This project aims to develop a holistic approach for reliable positioning for Intelligent Transport Systems (ITS). This project will address the challenges of integrity monitoring in ITS when using satellite-based technology, its integration with other sensors, and when supported by the proposed Australia National Positioning Infrastructure. It will consider Australian geography, large area, and sparse population, and emphasise rural tra ....Trustworthy positioning for intelligent transport systems. This project aims to develop a holistic approach for reliable positioning for Intelligent Transport Systems (ITS). This project will address the challenges of integrity monitoring in ITS when using satellite-based technology, its integration with other sensors, and when supported by the proposed Australia National Positioning Infrastructure. It will consider Australian geography, large area, and sparse population, and emphasise rural transport. Expected primary outputs include algorithms, a detailed analysis of required systems and recommendations that will help prepare Australia for the importation of self-driving vehicles.Read moreRead less
Three-dimensional property ownership map base for smart urban land administration. Three-dimensional property ownership map base for smart urban land administration. This project aims to support smart urban land administration by upgrading a two-dimensional (2D) property ownership map base to a three-dimensional (3D) map base, using 3D digital data from regulatory subdivision processes. The map base coherently represents all land-based parcels, and provides valuable intelligence used to make lan ....Three-dimensional property ownership map base for smart urban land administration. Three-dimensional property ownership map base for smart urban land administration. This project aims to support smart urban land administration by upgrading a two-dimensional (2D) property ownership map base to a three-dimensional (3D) map base, using 3D digital data from regulatory subdivision processes. The map base coherently represents all land-based parcels, and provides valuable intelligence used to make land and property decisions. The 2D map base omits above and underground properties and infrastructure common in urban settings, forcing stakeholders to rely on fragmented data streams. The 3D map base will provide a connected, digital source of intelligence about urban property objects. This is expected to reduce social and economic risks and enable more intelligent city planning and management.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560735
Funder
Australian Research Council
Funding Amount
$139,194.00
Summary
A Signal Simulation Facility for GNSS Receiver Design and Testing. The proposed Facility comprises a Global Navigation Satellite System (GNSS) RF Signal Simulator which allows laboratory testing of new signal tracking and navigation solution algorithms, under different scenarios. Simulation of the operation of current and future GPS satellites, and of the new European GNSS "Galileo", is vital for testing new receiver designs. For example, the Facility could be programmed to generate a GPS satell ....A Signal Simulation Facility for GNSS Receiver Design and Testing. The proposed Facility comprises a Global Navigation Satellite System (GNSS) RF Signal Simulator which allows laboratory testing of new signal tracking and navigation solution algorithms, under different scenarios. Simulation of the operation of current and future GPS satellites, and of the new European GNSS "Galileo", is vital for testing new receiver designs. For example, the Facility could be programmed to generate a GPS satellite signal with user-selectable physical variations in the signal path, including the presence of RF jamming sources, high atmospheric disturbances, diffraction effects and multipath. As many of the signal variations are rare and/or unpredictable, the Signal Simulator is the only means to carry out such tests.Read moreRead less