Skin friction control using engineering and biological surface coatings. The development of techniques to reduce skin friction in water conveying assets will increase renewable energy production from existing hydro-electric plant and improve the energy efficiency of water conveying utilities. There is also potential for application to marine biofouling problems and reducing fuel usage by shipping. Passive (non-chemical) and biological control methods to reduce fouling and friction will be sought ....Skin friction control using engineering and biological surface coatings. The development of techniques to reduce skin friction in water conveying assets will increase renewable energy production from existing hydro-electric plant and improve the energy efficiency of water conveying utilities. There is also potential for application to marine biofouling problems and reducing fuel usage by shipping. Passive (non-chemical) and biological control methods to reduce fouling and friction will be sought to minimise environmental impact and maintain potable water quality. This multidisciplinary project combining engineering, photogrammetry and biological sciences will provide valuable training for the project team members and develop a pool of skilled personnel available to Australian industries.Read moreRead less
Improvement of water conveying efficiency in hydroelectric power generation systems by optimising pipe friction losses. The growth of bacterial and algal slimes on the surface of water conveying system significantly reduces the net electricity generation from Tasmania's hydroelectric system.
The aim of this project is to develop an optimal maintenance strategy to control this growth which will balance maintenance downtime against the potential increase in electricity production. The growth resp ....Improvement of water conveying efficiency in hydroelectric power generation systems by optimising pipe friction losses. The growth of bacterial and algal slimes on the surface of water conveying system significantly reduces the net electricity generation from Tasmania's hydroelectric system.
The aim of this project is to develop an optimal maintenance strategy to control this growth which will balance maintenance downtime against the potential increase in electricity production. The growth response to cleaning techniques and surface coatings will be investigated.
The potential for increased power production from this renewable energy source will have considerable economic benefit for Tasmania.Read moreRead less
Determining generic indicators of stress in eucalypt leaves for application to the remote sensing of canopy condition and productivity modelling. Biotic and abiotic stresses induce generic alterations of leaf chemistry (e.g. chlorophyll, anthocyanins). We will explore the behaviour of eucalypt leaf reflectance to changes in leaf cellular chemistry and structure arising from exposure to a range of stressful factors. We will relate leaf reflectance to physiological processes using a research radia ....Determining generic indicators of stress in eucalypt leaves for application to the remote sensing of canopy condition and productivity modelling. Biotic and abiotic stresses induce generic alterations of leaf chemistry (e.g. chlorophyll, anthocyanins). We will explore the behaviour of eucalypt leaf reflectance to changes in leaf cellular chemistry and structure arising from exposure to a range of stressful factors. We will relate leaf reflectance to physiological processes using a research radiation interception model. We will report on a) the potential integration of data related to stress, into process-based models for eucalypt plantation growth and b) the exploitation of generic reflectance indicators of stress in the remote acquisition of high resolution multispectral imagery with potential to spatially quantify plantation eucalypt health.Read moreRead less
Smart Irrigation: integrating UAV soil moisture maps & variable rate sprays. This project will develop a state-of-the-art precision irrigation system for optimising water use and crop yield. Specifically, a novel UAV soil moisture mapping system based on passive microwave satellite remote sensing technology at L-band will be developed for near-surface soil moisture mapping at accuracies and spatial scales currently not attainable. These soil moisture maps will then be merged with irrigation wate ....Smart Irrigation: integrating UAV soil moisture maps & variable rate sprays. This project will develop a state-of-the-art precision irrigation system for optimising water use and crop yield. Specifically, a novel UAV soil moisture mapping system based on passive microwave satellite remote sensing technology at L-band will be developed for near-surface soil moisture mapping at accuracies and spatial scales currently not attainable. These soil moisture maps will then be merged with irrigation water delivery models to calibrate for spatial variation in soil properties and/or correct errors in spatial variation of rainfall and evapotranspiration inputs. Ultimately the water balance predictions will be used for implementation of variable rate irrigation control at scales hitherto unattainable.Read moreRead less
Ultrahigh-resolution remote sensing for assessing biodiversity hotspots. Robust indicators are central to the complex problem of conserving vegetation biodiversity. The project aims to address this by developing advanced techniques for interpreting data from ultrahigh-resolution remote sensing of essential indicators in Australian biodiversity hotspots. The expected benefit is to significantly advance international efforts in the large-scale validation of biodiversity indicators mapped from sate ....Ultrahigh-resolution remote sensing for assessing biodiversity hotspots. Robust indicators are central to the complex problem of conserving vegetation biodiversity. The project aims to address this by developing advanced techniques for interpreting data from ultrahigh-resolution remote sensing of essential indicators in Australian biodiversity hotspots. The expected benefit is to significantly advance international efforts in the large-scale validation of biodiversity indicators mapped from satellites.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100118
Funder
Australian Research Council
Funding Amount
$159,450.00
Summary
Sensor calibration facility for spectral and thermal remote sensing. This project aims to establish a calibration facility for the radiometric and spectral correction of hyperspectral and thermal sensors for ultrahigh-resolution remote sensing. Sensor calibration and characterisation is critical to the accuracy of hyperspectral and thermal data products, however, there is no central facility in Australia for this purpose. This project will provide significant benefits, such as growing our capaci ....Sensor calibration facility for spectral and thermal remote sensing. This project aims to establish a calibration facility for the radiometric and spectral correction of hyperspectral and thermal sensors for ultrahigh-resolution remote sensing. Sensor calibration and characterisation is critical to the accuracy of hyperspectral and thermal data products, however, there is no central facility in Australia for this purpose. This project will provide significant benefits, such as growing our capacity in ultrahigh-resolution remote sensing for ecosystem science, biosecurity, and disaster response.Read moreRead less
Experimental translocations to understand and combat eastern quoll declines. The project aims to understand the causes of observed declines of the eastern quoll in Tasmania, and develop tools to safeguard this species in their last wild stronghold. The project will test the innovative approach of undertaking a series of experimental translocations at an early stage of a population decline. This approach will provide reliable information on the causes of observed declines, while simultaneously te ....Experimental translocations to understand and combat eastern quoll declines. The project aims to understand the causes of observed declines of the eastern quoll in Tasmania, and develop tools to safeguard this species in their last wild stronghold. The project will test the innovative approach of undertaking a series of experimental translocations at an early stage of a population decline. This approach will provide reliable information on the causes of observed declines, while simultaneously testing the effectiveness of translocations of captive-bred animals as a management tool for the species. It will also develop evidence-based protocols for undertaking captive-bred translocations, to improve the outcomes of eastern quoll recovery efforts as well as promoting early intervention for other declining species. Read moreRead less
Bridging scales in remote sensing of vegetation stress. This project aims to develop operational upscaling algorithms to map vegetation stress indicators from space-borne missions’ optical observations of the Earth. These approaches use computer radiative transfer models and unmanned aircraft systems called drones, and will pave the way for regular satellite monitoring of plant health in extensive and inaccessible Australian and Antarctic areas. More accurate and timely remote sensing maps of ea ....Bridging scales in remote sensing of vegetation stress. This project aims to develop operational upscaling algorithms to map vegetation stress indicators from space-borne missions’ optical observations of the Earth. These approaches use computer radiative transfer models and unmanned aircraft systems called drones, and will pave the way for regular satellite monitoring of plant health in extensive and inaccessible Australian and Antarctic areas. More accurate and timely remote sensing maps of early stress symptoms will provide early warnings of droughts, diseases and pests, tell when and where to protect ecological functions of wild natural systems, and help to sustain or even increase agricultural food production.Read moreRead less
Towards an Active and Passive L- and P-band soil moisture satellite mission. This project tests alternate configurations for remote sensing of soil moisture using a new state-of-the-art Active/Passive (ie radar/radiometer) P-/L-band (ie microwave) satellite concept through a series of airborne field experiments. Timely soil moisture information is critical to improved water management for food production in the face of climate variability. The challenge is to do this accurately over large areas ....Towards an Active and Passive L- and P-band soil moisture satellite mission. This project tests alternate configurations for remote sensing of soil moisture using a new state-of-the-art Active/Passive (ie radar/radiometer) P-/L-band (ie microwave) satellite concept through a series of airborne field experiments. Timely soil moisture information is critical to improved water management for food production in the face of climate variability. The challenge is to do this accurately over large areas with an appropriate spatio-temporal detail, and for a soil depth that closely approximates the layer which impacts crop/pasture growth and influences management decisions. The longer P-band allows deeper penetration into the soil while the active/passive combination uses the respective resolution and accuracy characteristics.Read moreRead less
Advancing Antarctic science with a new high altitude platform capability. This project aims to address critical knowledge gaps in Antarctic science by engaging Australian scientists with the Australian aerospace industry to advance world-first high altitude scientific observations from a long-range stratospheric glider. The higher sensor resolution and adaptive mission planning of the glider at 20km altitude offers dramatic benefits over existing satellite platforms. The project will develop the ....Advancing Antarctic science with a new high altitude platform capability. This project aims to address critical knowledge gaps in Antarctic science by engaging Australian scientists with the Australian aerospace industry to advance world-first high altitude scientific observations from a long-range stratospheric glider. The higher sensor resolution and adaptive mission planning of the glider at 20km altitude offers dramatic benefits over existing satellite platforms. The project will develop the sensor payload of the glider, targeting research into Antarctic sea ice, atmospheric processes and seal populations. The project will build Australia’s research and innovation capacity through support for new collaboration between Australia's Antarctic scientists, geospatial specialists and remote-sensing platform developers.Read moreRead less