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
A combined inertial, satellite & terrestrial signal navigation device for high accuracy positioning & orientation of underground imaging systems. The 'holy grail' of the mapping community is ubiquitous, cm-level accuracy positioning/orientation in all outdoor environments with a minimum installed infrastructure and operational complexity. There is currently no system able to address such needs. The integration of an Australian-developed technology within the standard GPS/inertial navigation conf ....A combined inertial, satellite & terrestrial signal navigation device for high accuracy positioning & orientation of underground imaging systems. The 'holy grail' of the mapping community is ubiquitous, cm-level accuracy positioning/orientation in all outdoor environments with a minimum installed infrastructure and operational complexity. There is currently no system able to address such needs. The integration of an Australian-developed technology within the standard GPS/inertial navigation configuration would be a truly ground-breaking achievement. This would represent a significant enhancement of Australia's capacity to develop high-value navigation products and services, and the proposed project outcomes align closely with National Research Priority 3, and address the 'Frontier Technologies and Smart Information Use' priority goals.Read moreRead less
An Integrated Bridge Monitoring System Based on the GPS and Pseudolite Technologies. Global Positioning System (GPS) technology can be used for precise deflection measurement of manmade structures such as buildings, bridges, etc. When integrated with additional signals from pseudolites (PL) that transmit GPS-like signals, changes in the height(s) of the monitored point(s) can be measured to millimetre accuracy. In collaboration with University of Nottingham researchers, a bridge structure in the ....An Integrated Bridge Monitoring System Based on the GPS and Pseudolite Technologies. Global Positioning System (GPS) technology can be used for precise deflection measurement of manmade structures such as buildings, bridges, etc. When integrated with additional signals from pseudolites (PL) that transmit GPS-like signals, changes in the height(s) of the monitored point(s) can be measured to millimetre accuracy. In collaboration with University of Nottingham researchers, a bridge structure in the U.K. will be used as a testbed, and will be the first time that PLs have been used for such an application. The expected outcomes include a suite of deformation monitoring algorithms capable of online analysis of the combined GPS-PL outputs.Read moreRead less
Designing Next Generation GNSS Receivers Using the Software Approach. GNSS products & services are continually being developed to make Australian farmers & miners more productive, road transport & air & marine navigation safer, & geospatial data capture more efficient. The value of GNSS products & services will grow rapidly, and may be over a billion dollars pa in Australia by the end of the decade. In addition, the impact on society of ubiquitous positioning made possible using GNSS will be pro ....Designing Next Generation GNSS Receivers Using the Software Approach. GNSS products & services are continually being developed to make Australian farmers & miners more productive, road transport & air & marine navigation safer, & geospatial data capture more efficient. The value of GNSS products & services will grow rapidly, and may be over a billion dollars pa in Australia by the end of the decade. In addition, the impact on society of ubiquitous positioning made possible using GNSS will be profound. GNSS devices will be embedded within mobilephones, consumer items, clothing & other personal effects. An enhancement of Australia's R&D capabilities as proposed in this project will allow new GNSS receiver designs to be quickly developed & tested that take advantage of the next generation GNSS signals.Read moreRead less
Preparing for the next generation global navigation satellite system era: developing and testing new user and reference station receiver designs. The gross accumulated benefits of the widespread adoption of Gnss technology in the mining, agriculture and construction sectors alone by 2030 could be between $66B and $126B, primarily due to improvements in Gnss machine guidance systems - energy savings, reduction in carbon dioxide emissions, improved agricultural practices, etc. The national benefit ....Preparing for the next generation global navigation satellite system era: developing and testing new user and reference station receiver designs. The gross accumulated benefits of the widespread adoption of Gnss technology in the mining, agriculture and construction sectors alone by 2030 could be between $66B and $126B, primarily due to improvements in Gnss machine guidance systems - energy savings, reduction in carbon dioxide emissions, improved agricultural practices, etc. The national benefit would be enormous if the project could help facilitate the rapid and orderly introduction into Australia of high accuracy multi-constellation Gnss positioning technology. This project would also enable Australian researchers and industry to build up expertise in new Gnss signals and techniques, all crucial for supporting a local industry for next generation navigation products and services.Read moreRead less