Infrastructure Engineering - Theses

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    Modelling the flow regime of arid zone, floodplain rivers
    Costelloe, Justin Francis ( 2004-08)
    The requirements of ecological studies and water resource management plans are driving demand for hydrological models of the rivers of the arid zone. Knowledge of the hydrology of Australia’s arid zone is poor, yet is critical in understanding the ecology of the region. The research presented in this thesis seeks to address some shortcomings in our understanding of the hydrology of the Australian arid zone. In particular, the research examines the requirements for modelling the flow regime of arid zone rivers, concentrating on the rivers of the Lake Eyre Basin (LEB). The LEB has exceptionally low annual runoff of 3.5 mm, its major rivers develop over extremely low gradients and are characterised by very wide floodplains and complex anastomosing flow paths in their mid to lower reaches. This research was driven by both a practical and theoretical impetus. Practically, hydrological data were required at the water body scale for a large number of sites across three river systems of the LEB, for use in a study, known as ARIDFLO, of the ecological responses to hydrological conditions. Because of the remoteness of these sites and the paucity of gauging stations on these rivers, modelling of the rivers was the only method for delivering the required discharge data. Theoretically, the challenge was set for creating hydrological models for some extraordinarily complex river systems, in terms of their size, catchment characteristics and flow regime variability. (For complete abstract open document)
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    Modelling of flood patterns, using remote sensing, in the Coongie Lakes Wetlands, northeastern South Australia
    Costelloe, Justin Francis ( 1998)
    The Coongie Lakes is an area of freshwater wetlands located in the Strzelecki desert of north-eastern South Australia. The annual flood pulse from the unregulated Cooper Creek is the principal supply of water to this area of wetlands and of fundamental importance to the ecosystems of the wetlands. Understanding the hydrological factors that affect the flood patterns in arid zone wetlands is vital in the study of the ecology of the wetlands and when assessing the likely ecological effects of any upstream diversion of water from dry land rivers, such as Cooper Creek. The variability of the flood regime of dryland rivers requires that the flooding patterns from a range of flood pulses, with widely differing characteristics, be examined in order to best understand the subtle and complex interactions that are occurring. The use of the AVHRR, data provides the only viable synoptic and temporal coverage that can map the floodwater patterns during current and recent historic, large-scale flood events. The spatial and temporal distribution of floodwaters in the Coongie Lakes was mapped, using NOAA-AVHRR satellite imagery, for the period 1988-1990. Variations between images, not associated with the inherent albedo of the surface, were minimised by applying coefficients to the satellite data that corrected for the different path length of each image. These were measured for the centre of the image and this also minimised in-scene variations due to the wide view angle of the AVHRR. The images were not corrected for changes in atmospheric conditions between the different scenes. The effects of increased atmospheric haze levels and/or highly off-nadir view angles on some images was found to be quite significant and compromised the utility of the affected images in mapping out the distribution and movement of floodwaters. The floodwaters in the wetlands were identified using the ratio of NIR/Red<1('Ratio criterion') and also a NIR Threshold technique (‘Threshold criterion'). The NIR class ranges were selected following the single channel unsupervised classification of a representative subset of images. Three spectral classes were defined (0-16%, 16-23%, 23-30%) and were applied to all images. The floodwaters classes principally corresponded to the percentage of water surface within the pixel. A relationship was established between the spectral classes and depths of the floodwaters by calibrating the measured surface area of lakes against their known volumes. The accuracy of the AVHRR data in measuring the area of inundation was also evaluated by comparing selected images with Landsat MSS images and aerial photographs. The AVIHRR data underestimated the surface area of flooding by 20-30% using the Ratio criterion and 15- 20% range using the Threshold criterion. However, the latter criterion could grossly overestimate the area of flooding in regions of scattered water bodies and dark albedos. Comparing the volumes within the wetlands calculated using the satellite data and those n1easured by Cullyamurra gauge station in each of the three years of flooding (1988-90) gave an average underestimation by the Ratio criterion of 51 % and by the Threshold criterion of 35%. These underestimations also were caused by water losses other than by evaporation and so overstate the error range for the volume calculations. The range of flood pulse sizes observed during the study period were divided into five classes based on ranges for the peak daily flow amplitude and total volume of the flood pulse. The extent of flooding for each of these classes was defined. The monitoring of , ' the movement of a range of flood pulses through the wetlands also allowed the identification of the main controls on the patterns of inundation. The pattern of flooding within the wetlands was most influenced by the amplitude (peak and at flood head), shape and total volume of the flood pulse. Other critical factors included the pre-existing water volume in the wetlands, the flow rate, catchment source of the flooding and the floodplain volume capacity upstream of important geomorphological, flow-regulating features.