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
Network Design and Management for a Pseudolite and GPS Based Ubiquitous Positioning System. The Locata positioning technology uses a network of terrestrial based signal transmitters (pseudolites) and GPS satellites, to provide ubiquitous positioning (indoors and outdoors) in difficult environments. This research student project will focus on the intelligence associated with the pseudolite network such as: autonomous network installation, network integrity, and quality control. The implementati ....Network Design and Management for a Pseudolite and GPS Based Ubiquitous Positioning System. The Locata positioning technology uses a network of terrestrial based signal transmitters (pseudolites) and GPS satellites, to provide ubiquitous positioning (indoors and outdoors) in difficult environments. This research student project will focus on the intelligence associated with the pseudolite network such as: autonomous network installation, network integrity, and quality control. The implementation of innovative algorithms and methodologies developed in this research, will allow a robust, reliable and accurate positioning system for challenging indoor and outdoor environments, where current systems cannot work satisfactorily.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
Real-Time Integration of GPS with INS For Precise Long-Baseline Kinematic Positioning. Although Australian researchers have played an important role in the development of carrier phase-based GPS kinematic positioning algorithms and methodologies over the last two decades, investigations concerning high precision multi-sensor integration have been comparatively limited. This ARC project would go a significant way towards remedying this situation by building up theoretical and practical expertise ....Real-Time Integration of GPS with INS For Precise Long-Baseline Kinematic Positioning. Although Australian researchers have played an important role in the development of carrier phase-based GPS kinematic positioning algorithms and methodologies over the last two decades, investigations concerning high precision multi-sensor integration have been comparatively limited. This ARC project would go a significant way towards remedying this situation by building up theoretical and practical expertise in sensor integration techniques at the postdoctoral level. The outcomes of this project will represent a significant contribution to Australian R&D in the fields of precise positioning and navigation, since they will be directly applicable to the design and development of a variety of integrated multi-sensor systems.Read moreRead less
Structural Deformation Monitoring Integrating a New Wireless Positioning Technology with GPS. In today's society, current positioning technologies are unable to provide location information with the necessary accuracy, reliability, and low cost, for an expanding number of location aware applications. Locata's positioning technology has the potential to meet these requirements through a network of terrestrial based signal transmitters and GPS integration. The proposed research will provide adva ....Structural Deformation Monitoring Integrating a New Wireless Positioning Technology with GPS. In today's society, current positioning technologies are unable to provide location information with the necessary accuracy, reliability, and low cost, for an expanding number of location aware applications. Locata's positioning technology has the potential to meet these requirements through a network of terrestrial based signal transmitters and GPS integration. The proposed research will provide advanced training to graduate students and enable this technology to be realised. The application of the technology is almost limitless, from surveying and civil engineering projects, manufacturing industries and consumer Location Based Services (LBS), where the benefits would be enormous.Read moreRead less
Stochastic modelling for high precision GPS positioning applications. Realistic stochastic modelling for measurements is one of the fundamental and challenging issues in a wide range of scientific problems. This project aims to develop and test an innovative stochastic modelling methodology for high precision GPS positioning applications. The new stochastic modelling methodology will significantly improve the accuracy and reliability of satellite positioning results. The expected outcomes are ....Stochastic modelling for high precision GPS positioning applications. Realistic stochastic modelling for measurements is one of the fundamental and challenging issues in a wide range of scientific problems. This project aims to develop and test an innovative stochastic modelling methodology for high precision GPS positioning applications. The new stochastic modelling methodology will significantly improve the accuracy and reliability of satellite positioning results. The expected outcomes are: (1) new knowledge about the statistical characteristics of satellite measurements; (2) development of a new error analysis framework; and (3) development of computationally efficient data processing algorithms to support high precision GPS positioning applications.Read moreRead less
Robust Positioning Based on Ultra-Tight Integration of GPS, Pseudolites and Inertial Sensors. The Global Positioning System (GPS) has been becoming an increasingly important part of the world-wide geo-spatial information infrastructure. However, the availability and reliability of GPS positioning are still major challenging issues. This project proposes a new concept of robust positioning based on the ultra-tight integration of GPS, pseudolites and inertial sensor. The expected outcomes include: ....Robust Positioning Based on Ultra-Tight Integration of GPS, Pseudolites and Inertial Sensors. The Global Positioning System (GPS) has been becoming an increasingly important part of the world-wide geo-spatial information infrastructure. However, the availability and reliability of GPS positioning are still major challenging issues. This project proposes a new concept of robust positioning based on the ultra-tight integration of GPS, pseudolites and inertial sensor. The expected outcomes include: 1) a novel sensor integration approach, 2) innovative smart antenna design, 3) efficient algorithms and quality control procedures for signal acquisition and tracking, which can effectively suppress interferences and enhance the weak signal tracking.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