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<br />- . <br /> <br />2 <br /> <br />that there were any changes in channel morphology between 1963 and <br />1964. The 1974. 1978. and 1986 photographs cover the entire study <br />area. All photographs are black and white. at various scales: <br />1952 - 1:20.000; 1963 - 1:24,000; 1974 - 1:31,680; 1978 1:33.000; and <br />1986 - 1:24.000. <br /> <br />Each photograph was fitted with a mylar overlay on which the photointerpre- <br />tation classes were drawn. The river channel was delineated by drawing <br />the high-water embankment lines and vegetated islands. Following photo- <br />interpretation. polygons were transferred to U.S. Geological Survey <br />standard map quadrangles. A map-o-graph transfer machine was used <br />to adjust the photographs to 1:24,000 scale. To maintain accuracy, <br />all roads. trails. and creeks on the photographs were matched with <br />the roads. trails, and creeks on the map bases. To calculate the length <br />of each reach of the river. a line was delineated through the middle <br />of the channel. This calculated length was used to determine average <br />channel width rather than estimated lengths in the Green River Wilderness <br />Desolation River Guide. The data were then digitized into a GIS (Geographic <br />Information System) using the GES (Geographic Entry System) software. <br />Acreage listings for each class in each year were tabulated, and black <br />and white map plots at 1:24,000 scale were produced for each 7.5 minute <br />quadrangle and each year. <br /> <br />The river was divided into alluvial and nonalluvial segments as delineated <br />by Joe Lyons, 0-753. River-miles 190 to 170 are alluvial, 170 to 142 <br />are nonalluvial, 142 to 117 are alluvial. Allowing for the discontinuous <br />nature of the 1952 photography, three sites were analyzed for changes <br />in predam channel morphology: site 1--river-miles 190 to 170 (alluvial), <br />site 2--river-miles 170 to 166 (nonalluvial), and site 3--river-miles <br />123 to 117 (alluvial). Four sites were analyzed for changes in postdam <br />channel morphology: site 1--river-miles 190 to 170 (alluvial). site 2-- <br />170 to 142 (nonalluvial), site 3--142 to 131 (alluvial), and site 4--128.3 <br />to 117 (alluvial). Total alluvial river-miles analyzed were 41.8 and <br />total nonalluvial river-miles were 27.4. <br /> <br />The errors associated with interpreting aerial photography are the <br />consistency of the interpreter(s) and pencil line widths. Minimizing <br />incorrect boundary delineation is accomplished when only one interpreter <br />is used in making consistent subjective boundary decisions. One tenth <br />of 1 inch represents 200 feet at 1:24,000 scale aerial photography, <br />and the average pencil width represents approximately 10 feet. Therefore. <br />when one interpreter is used, photointerpretation of the range of scales <br />used in this study is accurate to within f20 feet. Additional error <br />can be found in the transfer and digitizing procedures. The transfer <br />process produces map products at the correct scale; however. the geographic <br />placement may be slightly incorrect. The digitizing process has been <br />proven to be highly accurate with very complex data sets. and this <br />data set is believed to be almost 100 percent accurate. There is no <br />method to numerically determine the error involved in either the transfer <br />process or the digitizing process. In conclusion. we believe that <br />with the scale of the photography used, all results reported in this <br />paper are accurate to f20 feet. <br />