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Statistical Data Analysis Explained. Applied Environmental Statistics with R. Edition No. 1

  • ID: 2180898
  • Book
  • April 2008
  • 362 Pages
  • John Wiley and Sons Ltd
Few books on statistical data analysis in the natural sciences are written at a level that a non-statistician will easily understand. This is a book written in colloquial language, avoiding mathematical formulae as much as possible, trying to explain statistical methods using examples and graphics instead. To use the book efficiently, readers should have some computer experience. The book starts with the simplest of statistical concepts and carries readers forward to a deeper and more extensive understanding of the use of statistics in environmental sciences. The book concerns the application of statistical and other computer methods to the management, analysis and display of spatial data. These data are characterised by including locations (geographic coordinates), which leads to the necessity of using maps to display the data and the results of the statistical methods. Although the book uses examples from applied geochemistry, and a large geochemical survey in particular, the principles and ideas equally well apply to other natural sciences, e.g., environmental sciences, pedology, hydrology, geography, forestry, ecology, and health sciences/epidemiology.

The book is unique because it supplies direct access to software solutions (based on R, the Open Source version of the S-language for statistics) for applied environmental statistics. For all graphics and tables presented in the book, the R-scripts are provided in the form of executable R-scripts. In addition, a graphical user interface for R, called DAS+R, was developed for convenient, fast and interactive data analysis.

Statistical Data Analysis Explained: Applied Environmental Statistics with R provides, on an accompanying website, the software to undertake all the procedures discussed, and the data employed for their description in the book.

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About the Authors.

1. Introduction.

1.1 The Kola Ecogeochemistry Project.

2. Preparing the Data for Use in R and DAS+R.

2.1 Required data format for import into R and DAS+R.

2.2 The detection limit problem.

2.3 Missing Values.

2.4 Some “typical” problems encountered when editing a laboratory data report file to a DAS+R file.

2.5 Appending and linking data files.

2.6 Requirements for a geochemical database.

2.7 Summary.

3. Graphics to Display the Data Distribution.

3.1 The one-dimensional scatterplot.

3.2 The histogram.

3.3 The density trace.

3.4 Plots of the distribution function.

3.5 Boxplots.

3.6 Combination of histogram, density trace, one-dimensional scatterplot, boxplot, and ECDF-plot.

3.7 Combination of histogram, boxplot or box-and-whisker plot, ECDF-plot, and CP-plot.

3.8 Summary.

4. Statistical Distribution Measures.

4.1 Central value.

4.2 Measures of spread.

4.3 Quartiles, quantiles and percentiles.

4.4 Skewness.

4.5 Kurtosis.

4.6 Summary table of statistical distribution measures.

4.7 Summary.

5. Mapping Spatial Data.

5.1 Map coordinate systems (map projection).

5.2 Map scale.

5.3 Choice of the base map for geochemical mapping

5.4 Mapping geochemical data with proportional dots.

5.5 Mapping geochemical data using classes.

5.6 Surface maps constructed with smoothing techniques.

5.7 Surface maps constructed with kriging.

5.8 Colour maps.

5.9 Some common mistakes in geochemical mapping.

5.10 Summary.

6. Further Graphics for Exploratory Data Analysis.

6.1 Scatterplots (xy-plots).

6.2 Linear regression lines.

6.3 Time trends.

6.4 Spatial trends.

6.5 Spatial distance plot.

6.6 Spiderplots (normalized multi-element diagrams).

6.7 Scatterplot matrix.

6.8 Ternary plots.

6.9 Summary.

7. Defining Background and Threshold, Identification of Data Outliers and Element Sources.

7.1 Statistical methods to identify extreme values and data outliers.

7.2 Detecting outliers and extreme values in the ECDF- or CP-plot.

7.3 Including the spatial distribution in the definition of background.

7.4 Methods to distinguish geogenic from anthropogenic element sources.

7.5 Summary.

8. Comparing Data in Tables and Graphics.

8.1 Comparing data in tables.

8.2 Graphical comparison of the data distributions of several data sets.

8.3 Comparing the spatial data structure.

8.4 Subset creation – a mighty tool in graphical data analysis.

8.5 Data subsets in scatterplots.

8.6 Data subsets in time and spatial trend diagrams.

8.7 Data subsets in ternary plots.

8.8 Data subsets in the scatterplot matrix.

8.9 Data subsets in maps.

8.10 Summary.

9. Comparing Data Using Statistical Tests.

9.1 Tests for distribution (Kolmogorov–Smirnov and Shapiro–Wilk tests).

9.2 The one-sample t-test (test for the central value).

9.3 Wilcoxon signed-rank test.

9.4 Comparing two central values of the distributions of independent data groups.

9.5 Comparing two central values of matched pairs of data.

9.6 Comparing the variance of two test.

9.7 Comparing several central values.

9.8 Comparing the variance of several data groups.

9.9 Comparing several central values of dependent groups.

9.10 Summary.

10. Improving Data Behaviour for Statistical Analysis: Ranking and Transformations.

10.1 Ranking/sorting.

10.2 Non-linear transformations.

10.3 Linear transformations.

10.4 Preparing a data set for multivariate data analysis.

10.5 Transformations for closed number systems.

10.6 Summary.

11. Correlation.

11.1 Pearson correlation.

11.2 Spearman rank correlation.

11.3 Kendall-tau correlation.

11.4 Robust correlation coefficients.

11.5 When is a correlation coefficient significant?

11.6 Working with many variables.

11.7 Correlation analysis and inhomogeneous data.

11.8 Correlation results following addictive logratio or central logratio transformations.

11.9 Summary.

12. Multivariate Graphics.

12.1 Profiles.

12.2 Stars.

12.3 Segments.

12.4 Boxes.

12.5 Castles and trees.

12.6 Parallel coordinates plot.

12.7 Summary.

13. Multivariate Outlier Detection.

13.1 Univariate versus multivariate outlier detection.

13.2 Robust versus non-robust outlier detection.

13.3 The chi-square plot.

13.4 Automated multivariate outlier detection and visualization.

13.5 Other graphical approaches for identifying outliers and groups.

13.6 Summary.

14. Principal Component Analysis (PCA) and Factor Analysis (FA).

14.1 Conditioning the data for PCA and FA.

14.2 Principal component analysis (PCA).

14.3 Factor Analysis.

14.4 Summary.

15. Cluster Analysis.

15.1 Possible data problems in the context of cluster analysis.

15.2 Distance measures.

15.3 Clustering samples.

15.4 Clustering variables.

15.5 Evaluation of cluster validity.

15.6 Selection of variables for cluster analysis.

15.7 Summary.

16. Regression Analysis (RA).

16.1 Data requirements for regression analysis.

16.2 Multiple regression.

16.3 Classical least squares (LS) regression.

16.4 Robust regression.

16.5 Model selection in regression analysis.

16.6 Other regression methods.

16.7 Summary.

17. Discriminant Analysis (DA) and Other Knowledge-Based Classification Methods.

17.1 Methods for discriminant analysis.

17.2 Data requirements for discriminant analysis.

17.3 Visualisation of the discriminant function.

17.4 Prediction with discriminant analysis.

17.5 Exploring for similar data structures.

17.6 Other knowledge-based classification methods/

17.7 Summary.

18. Quality Control (QC).

18.1 Randomised samples.

18.2 Trueness.

18.3 Accuracy.

18.4 Precision.

18.5 Analysis of variance (ANOVA)

18.6 Using Maps to assess data quality.

18.7 Variables analysed by two different analytical techniques.

18.8 Working with censored data – a practical example.

18.9 Summary.

19. Introduction to R and Structure of the DAS+R Graphical User Interface.

19.1 R.

19.2 R-scripts.

19.3 A brief overview of relevant R commands.

19.4 DAS+R.

19.5 Summary.



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Clemens Reimann Geological Survey of Norway, Trondheim, Norway.

Peter Filzmoser Institute of Statistics, Vienna University of Technology, Austria.

Robert Garrett Geological Survey of Canada, Natural Resources Canada, Ottawa, Canada.

Rudolf Dutter Institute of Statistics, Vienna University of Technology,  Austria.
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