A METHOD FOR MAPPING THE SPATIAL DISTRIBUTION 
OF SUSPENDED SEDIMENTS WITHIN LAKES OR RESERVOIRS 
USING LANDSAT MULTISPECTRAL SCANNER DATA 
John Harrington, Jr., Frank Schiebe, and John Ross 
USDA Agricultural Research Service 
Water Quality and Watershed Research Laboratory 
Durant, OK 74702 
ABSTRACT 
The cost of in situ sampling for water quality precludes frequent observation. Remote sensing satellites provide 
an alternative means for obtaining detailed information concerning the synoptic patterns of suspended sediment 
within surface waters. This paper discusses the methods used to prepare thematic maps of the spatial pattern 
of suspended sediment variation within Lake Thunderbird,a water supply and flood control reservoir in central 
Oklahoma. Landsat MSS data for 15 dates from 1987 and 1988 were analyzed and mapped. Areas within the 
reservoir corresponding to five distinct classes of suspended sediment concentration (i.e., 0-25 mg/1, 25-50 mg/1, 
50-75 mg/1, 75-100 mg/1, and > 100 mg/1) were determined for each date. Examination of these thematic maps 
provides important insights concerning the physical limnological cycle for Lake Thunderbirdand the size of the 
reservoir area impacted by sediment laden runoff from precipitation events of varying magnitude. 
The method used in producing the thematic maps involves use of a theoretically-derived exponential equation 
that relates the exoatmospheric reflectance recorded by the Landsat satellite to suspended sediment 
concentrations. This equation was calibrated using data from 16 lakes in southcentral Oklahoma. The raw 
Landsat MSS digital numbers are converted to corresponding suspended sediment concentration using the 
exponential equation. An atmospheric correction factor that also takes into account the problems introduced 
by the cubic convolution transformation used in geometric correction of the data is incorporated in this data 
transformation. The atmospheric correction and thematic classification is applied to Landsat MSS band 3 data. 
The importance of this capability for global water quality monitoring will be identified. In addition, potential 
problems associated with the transfer to this procedure to other environments will be addressed. 
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