Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560930
Funder
Australian Research Council
Funding Amount
$167,777.00
Summary
Airborne laser scanning for advanced environmental monitoring. This proposal seeks to enhance the national capability for airborne remote sensing of key environmental variables through the acquisition of an airborne laser scanner and inertial navigation system. Many environmental science studies, such as hydrology, soil moisture scaling and salinity, can be significantly enhanced by airborne laser scanning, through the creation of high precision, high resolution digital terrain models. Airborne ....Airborne laser scanning for advanced environmental monitoring. This proposal seeks to enhance the national capability for airborne remote sensing of key environmental variables through the acquisition of an airborne laser scanner and inertial navigation system. Many environmental science studies, such as hydrology, soil moisture scaling and salinity, can be significantly enhanced by airborne laser scanning, through the creation of high precision, high resolution digital terrain models. Airborne laser scanning can also measure three dimensional vegetation canopy structure, a useful indicator of biomass, carbon storage and vegetation health. This infrastructure will provide Australian researchers with a unique arsenal of remote sensing tools for advanced yet affordable environmental research studies.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
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
Dynamic Receiver Autonomous Integrity Monitoring for Multi-constellation Global Navigation Satellite Systems. In the next five years, four Global Navigation Satellite Systems (GNSS) will be developed to foster the wide applications of satellite navigation in our daily life. These new developments can certainly offer a variety of economic, scientific and social opportunities for Australia. This research project will develop a theoretically sound integrity monitoring procedure for the new generat ....Dynamic Receiver Autonomous Integrity Monitoring for Multi-constellation Global Navigation Satellite Systems. In the next five years, four Global Navigation Satellite Systems (GNSS) will be developed to foster the wide applications of satellite navigation in our daily life. These new developments can certainly offer a variety of economic, scientific and social opportunities for Australia. This research project will develop a theoretically sound integrity monitoring procedure for the new generation GNSS receivers to check their own navigation performance. The contribution from this research, which is patentable, will bring a timely opportunity for local industry to develop new products towards a massive worldwide market and serve Australian users as well.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
A Positioning System for Mobile Phones. This project aims to produce a positioning system that integrates a mobile phone-based technique developed in Australia, known as Seekerzone, with GPS. The combination of Seekerzone and GPS delivers a system capable of reporting whether children or valuables are in a safe location. As security becomes an increasing priority, this system can operate indoors or outdoors, and provides many solutions. Seekerzone has already attracted international interest, an ....A Positioning System for Mobile Phones. This project aims to produce a positioning system that integrates a mobile phone-based technique developed in Australia, known as Seekerzone, with GPS. The combination of Seekerzone and GPS delivers a system capable of reporting whether children or valuables are in a safe location. As security becomes an increasing priority, this system can operate indoors or outdoors, and provides many solutions. Seekerzone has already attracted international interest, and coupled with GPS, its applications and export opportunities will multiply. The target product will provide effective and convenient security, while its developemnt will provide important research training in Australia's drastically under-resourced spatial industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560920
Funder
Australian Research Council
Funding Amount
$129,800.00
Summary
Field spectroradiometer and associated equipment for quantitative measurement and characterization of biophysical features and calibration of remotely sensed imagery. This set of equipment will improve and extend existing research capabilities in the field of in-situ remote sensing research and applications, for both aquatic and terrestrial environments. It will contribute to knowledge regarding terrestrial, coastal and estuarine vegetation and linkages to environmental change and will assist in ....Field spectroradiometer and associated equipment for quantitative measurement and characterization of biophysical features and calibration of remotely sensed imagery. This set of equipment will improve and extend existing research capabilities in the field of in-situ remote sensing research and applications, for both aquatic and terrestrial environments. It will contribute to knowledge regarding terrestrial, coastal and estuarine vegetation and linkages to environmental change and will assist in the development of new algorithms, indices and techniques of vegetation discrimination from remotely sensed imagery. It will help in the understanding of reflectance in plants under stress or pest damage. The spectroradiometer will enable the group to expand applications in the field of urban fire hazard mapping, precision agriculture, crop physiology, species mapping, viticulture and canopy modelling.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
Full-Waveform Lidar Remote Sensing for Forest Inventory. Australia has the sixth largest forest area in the world, consisting of 164 million hectares covering 21% of the continent. The Australian government has invested in research for management of forests by construction of forest database and detection of forest change. The successful application of full-waveform lidar data for the extraction of plot statistics such as percentile tree counts, stem measurement, canopy cover and leaf area inde ....Full-Waveform Lidar Remote Sensing for Forest Inventory. Australia has the sixth largest forest area in the world, consisting of 164 million hectares covering 21% of the continent. The Australian government has invested in research for management of forests by construction of forest database and detection of forest change. The successful application of full-waveform lidar data for the extraction of plot statistics such as percentile tree counts, stem measurement, canopy cover and leaf area index, will contribute to forest resource management and analysis. Significantly, this research will be of benefit to Forests New South Wales as well as the many industries that require reliable forest resource data, such as land care, national defence, emergency services, and fire fighting authorities.Read moreRead less