Statistical Data Analysis Explained

Clemens Reiman (born 1952) holds an M.Sc. in Mineralogy and Petrology from the University of Hamburg (Germany), a Ph.D. in Geosciences from Leoben Mining University, Austria, and a D.Sc. in Applied Geochemistry from the same university. he has worked as a lecturer in Mineralogy and Petrology and Environmental Sciences at Leoben Mining University, as an exploration geochemist in eastern Canada, in contract research in environmental sciences in Austria and managed the laboratory of an Austrian cement company before joining the Geological Survey of Norway in 1991 as a senior geochemist. From March to October 2004 he was director and professor at the German Federal Environment Agency (Unweltbundesamt, UBAS), responsible for the Division II, Environmental Health and Protection of Ecosystems. At present he is chairman of the EuroGeoSurveys geochemistry expert group, acting vice president of the International Association of GeoChemistry (IAGC), and associate editor of both Applied Geochemistry and Geochemistry: Exploration, Environment, Analysis. Peter Filzmoser (born 1968) studies Applied Mathematics at the Vienna University of Technology, Austria, where he also wrote his doctoral thesis and habilitation devoted to the field of multivariate statistics. His research led him to the area of robust statistics, resulting in many international collaborations and various scientific papers in this area. His interest in applications of robust methods resulted in the development of R software packages. He was and is involved in the Organisation of several scientific evens devoted to robust statistics. Since 2001 he has been dozent at the Statistics Department at Vienna University of Technology. He was visiting professor at the universities of Vienna, Toulouse and Minsk. Robert G. Garrett (Bob Garrett) studied Mining Geology and Applied Geochemistry at Imperial College, London, and joined the Geological Survey of Canada (GSC) in 1967 following post-doctoral studies at Northwestern University, Evanston. For the next 25 years his activities focused on regional geochemical mapping in Canada, and overseas for the Canadian International Development Agency, to support mineral exploration and resource appraisal. Throughout his work there has been a use of computers and statistics to manage data, assess their quality, and maximise the knowledge extracted from them. In the 1990s he commenced collaboration crops. Since then he has been involved in various Canadian Federal and university-based research initiatives aimed at providing sound science to support Canadian regulatory and international policy activities concerning risk assessments and risk management for metals. he retired in March 2005 but remains active as an Emeritus Scientist. Rudolf Dutter is senior statistician and full professor at Vienna University of Technology, Austria. he studies Applied Mathematics in Vienna (M.Sc.) and Statistics at Universite de Montreal, Canada (Ph.D.). He spent three years as a post-doctoral fellow at ETH, Zurich, working on computational robust statistics. research and teaching activities followed at the Graz University of Technology, and as a full professor of statistics at Vienna University of Technology, both in Austria. he also taught and consulted at Leoben Mining University, Technology, both in Austria. he also taught and consulted at Leoben Mining University, Austria; currently he consults in many fields of applied statistics with main interests in computational and robust statistics, development of statistical software, and geostatistics. He is author and coauthor of many publications and several books, e.g., an early booklet in German on geostatistics.

Preface xiii

Acknowledgements xv

About the authors xvii

1 Introduction 1

1.1 The Kola Ecogeochemistry Project 5

1.1.1 Short description of the Kola Project survey area 6

1.1.2 Sampling and characteristics of the different sample materials 9

1.1.3 Sample preparation and chemical analysis 11

2 Preparing the Data for Use in R and DAS+R 13

2.1 Required data format for import into R and DAS+R 14

2.2 The detection limit problem 17

2.3 Missing values 20

2.4 Some "typical" problems encountered when editing a laboratory data report file to a DAS+R file 21

2.4.1 Sample identification 22

2.4.2 Reporting units 22

2.4.3 Variable names 23

2.4.4 Results below the detection limit 23

2.4.5 Handling of missing values 24

2.4.6 File structure 24

2.4.7 Quality control samples 25

2.4.8 Geographical coordinates, further editing and some unpleasant limitations of spreadsheet programs 25

2.5 Appending and linking data files 25

2.6 Requirements for a geochemical database 27

2.7 Summary 28

3 Graphics to Display the Data Distribution 29

3.1 The one-dimensional scatterplot 29

3.2 The histogram 31

3.3 The density trace 34

3.4 Plots of the distribution function 35

3.4.1 Plot of the cumulative distribution function (CDF-plot) 35

3.4.2 Plot of the empirical cumulative distribution function (ECDF-plot) 36

3.4.3 The quantile-quantile plot (QQ-plot) 36

3.4.4 The cumulative probability plot (CP-plot) 39

3.4.5 The probability-probability plot (PP-plot) 40

3.4.6 Discussion of the distribution function plots 41

3.5 Boxplots 41

3.5.1 The Tukey boxplot 42

3.5.2 The log-boxplot 44

3.5.3 The percentile-based boxplot and the box-and-whisker plot 46

3.5.4 The notched boxplot 47

3.6 Combination of histogram, density trace, one-dimensional scatterplot, boxplot, and ECDF-plot 48

3.7 Combination of histogram, boxplot or box-and-whisker plot, ECDF-plot, and CP-plot 49

3.8 Summary 50

4 Statistical Distribution Measures 51

4.1 Central value 51

4.1.1 The arithmetic mean 51

4.1.2 The geometric mean 52

4.1.3 The mode 52

4.1.4 The median 52

4.1.5 Trimmed mean and other robust measures of the central value 53

4.1.6 Influence of the shape of the data distribution 53

4.2 Measures of spread 56

4.2.1 The range 56

4.2.2 The interquartile range (IQR) 56

4.2.3 The standard deviation 57

4.2.4 The median absolute deviation (MAD) 57

4.2.5 Variance 58

4.2.6 The coefficient of variation (CV) 58

4.2.7 The robust coefficient of variation (CVR) 59

4.3 Quartiles, quantiles and percentiles 59

4.4 Skewness 59

4.5 Kurtosis 59

4.6 Summary table of statistical distribution measures 60

4.7 Summary 60

5 Mapping Spatial Data 63

5.1 Map coordinate systems (map projection) 64

5.2 Map scale 65

5.3 Choice of the base map for geochemical mapping 66

5.4 Mapping geochemical data with proportional dots 68

5.5 Mapping geochemical data using classes 69

5.5.1 Choice of symbols for geochemical mapping 70

5.5.2 Percentile classes 71

5.5.3 Boxplot classes 71

5.5.4 Use of ECDF- and CP-plot to select classes for mapping 74

5.6 Surface maps constructed with smoothing techniques 74

5.7 Surface maps constructed with kriging 76

5.7.1 Construction of the (semi)variogram 76

5.7.2 Quality criteria for semivariograms 79

5.7.3 Mapping based on the semivariogram (kriging) 79

5.7.4 Possible problems with semivariogram estimation and kriging 80

5.8 Colour maps 82

5.9 Some common mistakes in geochemical mapping 84

5.9.1 Map scale 84

5.9.2 Base map 84

5.9.3 Symbol set 84

5.9.4 Scaling of symbol size 84

5.9.5 Class selection 86

5.10 Summary 88

6 Further Graphics for Exploratory Data Analysis 91

6.1 Scatterplots (xy-plots) 91

6.1.1 Scatterplots with user-defined lines or fields 92

6.2 Linear regression lines 93

6.3 Time trends 95

6.4 Spatial trends 97

6.5 Spatial distance plot 99

6.6 Spiderplots (normalised multi-element diagrams) 101

6.7 Scatterplot matrix 102

6.8 Ternary plots 103

6.9 Summary 106

7 Defining Background and Threshold, Identification of Data Outliers and Element Sources 107

7.1 Statistical methods to identify extreme values and data outliers 108

7.1.1 Classical statistics 108

7.1.2 The boxplot 109

7.1.3 Robust statistics 110

7.1.4 Percentiles 111

7.1.5 Can the range of background be calculated? 112

7.2 Detecting outliers and extreme values in the ECDF- or CP-plot 112

7.3 Including the spatial distribution in the definition of background 114

7.3.1 Using geochemical maps to identify a reasonable threshold 114

7.3.2 The concentration-area plot 115

7.3.3 Spatial trend analysis 118

7.3.4 Multiple background populations in one data set 119

7.4 Methods to distinguish geogenic from anthropogenic element sources 120

7.4.1 The TOP/BOT-ratio 120

7.4.2 Enrichment factors (EFs) 121

7.4.3 Mineralogical versus chemical methods 128

7.5 Summary 128

8 Comparing Data in Tables and Graphics 129

8.1 Comparing data in tables 129

8.2 Graphical comparison of the data distributions of several data sets 133

8.3 Comparing the spatial data structure 136

8.4 Subset creation – a mighty tool in graphical data analysis 138

8.5 Data subsets in scatterplots 141

8.6 Data subsets in time and spatial trend diagrams 142

8.7 Data subsets in ternary plots 144

8.8 Data subsets in the scatterplot matrix 146

8.9 Data subsets in maps 147

8.10 Summary 148

9 Comparing Data Using Statistical Tests 149

9.1 Tests for distribution (Kolmogorov–Smirnov and Shapiro–Wilk tests) 150

9.1.1 The Kola data set and the normal or lognormal distribution 151

9.2 The one-sample t-test (test for the central value) 154

9.3 Wilcoxon signed-rank test 156

9.4 Comparing two central values of the distributions of independent data groups 157

9.4.1 The two-sample t-test 157

9.4.2 The Wilcoxon rank sum test 158

9.5 Comparing two central values of matched pairs of data 158

9.5.1 The paired t-test 158

9.5.2 The Wilcoxon test 160

9.6 Comparing the variance of two data sets 160

9.6.1 The F-test 160

9.6.2 The Ansari–Bradley test 160

9.7 Comparing several central values 161

9.7.1 One-way analysis of variance (ANOVA) 161

9.7.2 Kruskal-Wallis test 161

9.8 Comparing the variance of several data groups 161

9.8.1 Bartlett test 161

9.8.2 Levene test 162

9.8.3 Fligner test 162

9.9 Comparing several central values of dependent groups 163

9.9.1 ANOVA with blocking (two-way) 163

9.9.2 Friedman test 163

9.10 Summary 164

10 Improving Data Behaviour for Statistical Analysis: Ranking and Transformations 167

10.1 Ranking/sorting 168

10.2 Non-linear transformations 169

10.2.1 Square root transformation 169

10.2.2 Power transformation 169

10.2.3 Log(arithmic)-transformation 169

10.2.4 Box–Cox transformation 171

10.2.5 Logit transformation 171

10.3 Linear transformations 172

10.3.1 Addition/subtraction 172

10.3.2 Multiplication/division 173

10.3.3 Range transformation 174

10.4 Preparing a data set for multivariate data analysis 174

10.4.1 Centring 174

10.4.2 Scaling 174

10.5 Transformations for closed number systems 176

10.5.1 Additive logratio transformation 177

10.5.2 Centred logratio transformation 178

10.5.3 Isometric logratio transformation 178

10.6 Summary 179

11 Correlation 181

11.1 Pearson correlation 182

11.2 Spearman rank correlation 183

11.3 Kendall-tau correlation 184

11.4 Robust correlation coefficients 184

11.5 When is a correlation coefficient significant? 185

11.6 Working with many variables 185

11.7 Correlation analysis and inhomogeneous data 187

11.8 Correlation results following additive logratio or centred logratio transformations 189

11.9 Summary 191

12 Multivariate Graphics 193

12.1 Profiles 193

12.2 Stars 194

12.3 Segments 196

12.4 Boxes 197

12.5 Castles and trees 198

12.6 Parallel coordinates plot 198

12.7 Summary 200

13 Multivariate Outlier Detection 201

13.1 Univariate versus multivariate outlier detection 201

13.2 Robust versus non-robust outlier detection 204

13.3 The chi-square plot 205

13.4 Automated multivariate outlier detection and visualisation 205

13.5 Other graphical approaches for identifying outliers and groups 208

13.6 Summary 210

14 Principal Component Analysis (PCA) and Factor Analysis (FA) 211

14.1 Conditioning the data for PCA and FA 212

14.1.1 Different data ranges and variability, skewness 212

14.1.2 Normal distribution 213

14.1.3 Data outliers 213

14.1.4 Closed data 214

14.1.5 Censored data 215

14.1.6 Inhomogeneous data sets 215

14.1.7 Spatial dependence 215

14.1.8 Dimensionality 216

14.2 Principal component analysis (PCA) 216

14.2.1 The scree plot 217

14.2.2 The biplot 219

14.2.3 Mapping the principal components 220

14.2.4 Robust versus classical PCA 221

14.3 Factor analysis 222

14.3.1 Choice of factor analysis method 224

14.3.2 Choice of rotation method 224

14.3.3 Number of factors extracted 224

14.3.4 Selection of elements for factor analysis 225

14.3.5 Graphical representation of the results of factor analysis 225

14.3.6 Robust versus classical factor analysis 229

14.4 Summary 231

15 Cluster Analysis 233

15.1 Possible data problems in the context of cluster analysis 234

15.1.1 Mixing major, minor and trace elements 234

15.1.2 Data outliers 234

15.1.3 Censored data 235

15.1.4 Data transformation and standardisation 235

15.1.5 Closed data 235

15.2 Distance measures 236

15.3 Clustering samples 236

15.3.1 Hierarchical methods 236

15.3.2 Partitioning methods 239

15.3.3 Model-based methods 240

15.3.4 Fuzzy methods 242

15.4 Clustering variables 242

15.5 Evaluation of cluster validity 244

15.6 Selection of variables for cluster analysis 246

15.7 Summary 247

16 Regression Analysis (RA) 249

16.1 Data requirements for regression analysis 251

16.1.1 Homogeneity of variance and normality 251

16.1.2 Data outliers, extreme values 253

16.1.3 Other considerations 253

16.2 Multiple regression 254

16.3 Classical least squares (LS) regression 255

16.3.1 Fitting a regression model 255

16.3.2 Inferences from the regression model 256

16.3.3 Regression diagnostics 259

16.3.4 Regression with opened data 259

16.4 Robust regression 260

16.4.1 Fitting a robust regression model 261

16.4.2 Robust regression diagnostics 262

16.5 Model selection in regression analysis 264

16.6 Other regression methods 266

16.7 Summary 268

17 Discriminant Analysis (DA) and Other Knowledge-Based Classification Methods 269

17.1 Methods for discriminant analysis 269

17.2 Data requirements for discriminant analysis 270

17.3 Visualisation of the discriminant function 271

17.4 Prediction with discriminant analysis 272

17.5 Exploring for similar data structures 275

17.6 Other knowledge-based classification methods 276

17.6.1 Allocation 276

17.6.2 Weighted sums 278

17.7 Summary 280

18 Quality Control (QC) 281

18.1 Randomised samples 282

18.2 Trueness 282

18.3 Accuracy 284

18.4 Precision 286

18.4.1 Analytical duplicates 287

18.4.2 Field duplicates 289

18.5 Analysis of variance (ANOVA) 290

18.6 Using maps to assess data quality 293

18.7 Variables analysed by two different analytical techniques 294

18.8 Working with censored data – a practical example 296

18.9 Summary 299

19 Introduction to R and Structure of the DAS+R Graphical User Interface 301

19.1 R 301

19.1.1 Installing R 301

19.1.2 Getting started 302

19.1.3 Loading data 302

19.1.4 Generating and saving plots in R 303

19.1.5 Scatterplots 305

19.2 R-scripts 307

19.3 A brief overview of relevant R commands 311

19.4 DAS+R 315

19.4.1 Loading data into DAS+R 316

19.4.2 Plotting diagrams 316

19.4.3 Tables 317

19.4.4 Working with “worksheets” 317

19.4.5 Groups and subsets 317

19.4.6 Mapping 318

19.5 Summary 318

References 321

Index 337