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Robust graphical methods for diagnosing trend in irregularly spaced water quality time series

  • Graphics/Microcomputers
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Abstract

Graphical methods can play an important role in the reliable assessment of trends in typically ill behaved river quality data series both as diagnostic tools and as visual corroborative evidence when assumptions required for formal statistical tests are not met. Robust, graphically-oriented trend diagnosis procedures are presented for data series characterized by nonnormal populations, uneven time spacing, nonmonotonic trend and other factors which can create serious problems for standard parametric time series methods. Cleveland's robust locally weighted regression (RLWR) developed for investigating nonlinearity in x-y scatterplots is adapted as a robust/resistant smoothing filter for the analysis of irregular time series comprising quantitative observations. Low powered RLWR trend lines reveal temporally local phenomena, e.g. abrupt jumps (often associated with point source impacts) and periodicities, while higher powered RLWR yields smooth lines characterizing medium and longer term trends. Simple variants of Tukey smoothing concepts are developed for series with censored observations. Applications to Ontario river quality series reveal that graphical evidence is frequently sufficient to obviate the need for formal trend testing. The methods are generally applicable to most time series.

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  1. Water Resources Branch, Ontario Ministry of the Environment, 135 St. Clair Ave. W., M4V 1K6, Ontario, Toronto, Canada

    Byron A. Bodo

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  1. Byron A. Bodo
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Bodo, B.A. Robust graphical methods for diagnosing trend in irregularly spaced water quality time series. Environ Monit Assess 13, 407–428 (1989). https://doi.org/10.1007/BF00394242

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