Bayesian Networks for Probabilistic Inference andDecision Analysis in Forensic Science 2e
Buy Rights Online Buy Rights

Rights Contact Login For More Details

  • Wiley

More About This Title Bayesian Networks for Probabilistic Inference andDecision Analysis in Forensic Science 2e

English

"This book should have a place on the bookshelf of every forensic scientist who cares about the science of evidence interpretation"
Dr. Ian Evett, Principal Forensic Services Ltd, London, UK

Continuing developments in science and technology mean that the amounts of information forensic scientists are able to provide for criminal investigations is ever increasing. 
The commensurate increase in complexity creates difficulties for scientists and lawyers with regard to evaluation and interpretation, notably with respect to issues of inference and decision.
Probability theory, implemented through graphical methods, and specifically Bayesian networks, provides powerful methods to deal with this complexity. Extensions of these methods to elements
of decision theory provide further support and assistance to the judicial system.

Bayesian Networks for Probabilistic Inference and Decision Analysis in Forensic Science provides a unique and comprehensive introduction to the use of Bayesian decision networks for the evaluation and interpretation of scientific findings in forensic science, and for the support of decision-makers in their scientific and legal tasks.

• Includes self-contained introductions to probability and decision theory.
• Develops the characteristics of Bayesian networks, object-oriented Bayesian networks and their extension to decision models.
• Features implementation of the methodology with reference to commercial and academically available software.
• Presents standard networks and their extensions that can be easily implemented and that can assist in the reader’s own analysis of real cases.
• Provides a technique for structuring problems and organizing data based on methods and principles of scientific reasoning.
• Contains a method for the construction of coherent and defensible arguments for the analysis and evaluation of scientific findings and for decisions based on them.
• Is written in a lucid style, suitable for forensic scientists and lawyers with minimal mathematical background.
• Includes a foreword by Ian Evett.

The clear and accessible style of this second edition makes this book ideal for all forensic scientists, applied statisticians and graduate students wishing to evaluate forensic findings from the perspective of probability and decision analysis. It will also appeal to lawyers and other scientists and professionals interested in the evaluation and interpretation of forensic findings, including decision making based on scientific information.

 

English

Franco Taroni, Institute de Police Scientifique et de Criminologie, University of Lausanne, Switzerland.

Silvia Bozza, Department of Statistics, University Ca' Fosari, Venice, Italy.

Alex Biedermann, Bundeskriminalpolizei, Kommissariat Kriminaltechnik, Switzerland.

Paolo Garbolino, Faculty of Arts and Design, IUAV University, Venice, Italy.

Colin Aitken, School of Mathematics, University of Edinburgh, UK.

English

Foreword xiii

Preface to the second edition xvii

Preface to the first edition xxi

1 The logic of decision 1

1.1 Uncertainty and probability 1

1.1.1 Probability is not about numbers, it is about coherent reasoning under uncertainty 1

1.1.2 The first two laws of probability 2

1.1.3 Relevance and independence 3

1.1.4 The third law of probability 5

1.1.5 Extension of the conversation 6

1.1.6 Bayes’ theorem 6

1.1.7 Probability trees 7

1.1.8 Likelihood and probability 9

1.1.9 The calculus of (probable) truths 10

1.2 Reasoning under uncertainty 12

1.2.1 The Hound of the Baskervilles 12

1.2.2 Combination of background information and evidence 13

1.2.3 The odds form of Bayes’ theorem 15

1.2.4 Combination of evidence 16

1.2.5 Reasoning with total evidence 16

1.2.6 Reasoning with uncertain evidence 18

1.3 Population proportions, probabilities and induction 19

1.3.1 The statistical syllogism 19

1.3.2 Expectations and population proportions 21

1.3.3 Probabilistic explanations 22

1.3.4 Abduction and inference to the best explanation 25

1.3.5 Induction the Bayesian way 26

1.4 Decision making under uncertainty 28

1.4.1 Bookmakers in the Courtrooms? 28

1.4.2 Utility theory 29

1.4.3 The rule of maximizing expected utility 33

1.4.4 The loss function 34

1.4.5 Decision trees 35

1.4.6 The expected value of information 38

1.5 Further readings 42

2 The logic of Bayesian networks and influence diagrams 45

2.1 Reasoning with graphical models 45

2.1.1 Beyond detective stories 45

2.1.2 Bayesian networks 46

2.1.3 A graphical model for relevance 48

2.1.4 Conditional independence 50

2.1.5 Graphical models for conditional independence: d-separation 51

2.1.6 A decision rule for conditional independence 53

2.1.7 Networks for evidential reasoning 53

2.1.8 The Markov property 56

2.1.9 Influence diagrams 58

2.1.10 Conditional independence in influence diagrams 60

2.1.11 Relevance and causality 61

2.1.12 The Hound of the Baskervilles revisited 63

2.2 Reasoning with Bayesian networks and influence diagrams 65

2.2.1 Divide and conquer 66

2.2.2 From directed to triangulated graphs 67

2.2.3 From triangulated graphs to junction trees 69

2.2.4 Solving influence diagrams 71

2.2.5 Object-oriented Bayesian networks 74

2.2.6 Solving object-oriented Bayesian networks 79

2.3 Further readings 82

2.3.1 General 82

2.3.2 Bayesian networks and their predecessors in judicial contexts 83

3 Evaluation of scientific findings in forensic science 85

3.1 Introduction 85

3.2 The value of scientific findings 86

3.3 Principles of forensic evaluation and relevant propositions 90

3.3.1 Source level propositions 92

3.3.2 Activity level propositions 94

3.3.3 Crime level propositions 97

3.4 Pre-assessment of the case 100

3.5 Evaluation using graphical models 103

3.5.1 Introduction 103

3.5.2 General aspects of the construction of Bayesian networks 103

3.5.3 Eliciting structural relationships 105

3.5.4 Level of detail of variables and quantification of influences 106

3.5.5 Deriving an alternative network structure 108

4 Evaluation given source level propositions 113

4.1 General considerations 113

4.2 Standard statistical distributions 115

4.3 Two stains, no putative source 117

4.3.1 Likelihood ratio for source inference when no putative source is available 117

4.3.2 Bayesian network for a two-trace case with no putative source 119

4.3.3 An alternative network structure for a two trace no putative source case 121

4.4 Multiple propositions 122

4.4.1 Form of the likelihood ratio 122

4.4.2 Bayesian networks for evaluation given multiple propositions 123

5 Evaluation given activity level propositions 129

5.1 Evaluation of transfer material given activity level propositions assuming a direct source relationship 130

5.1.1 Preliminaries 130

5.1.2 Derivation of a basic structure for a Bayesian network 131

5.1.3 Modifying the basic network 134

5.1.4 Further considerations about background presence 137

5.1.5 Background from different sources 139

5.1.6 An alternative description of the findings 142

5.1.7 Bayesian network for an alternative description of findings 145

5.1.8 Increasing the level of detail of selected propositions 147

5.1.9 Evaluation of the proposed model 149

5.2 Cross- or two-way transfer of trace material 150

5.3 Evaluation of transfer material given activity level propositions with uncertainty about the true source 154

5.3.1 Network structure 154

5.3.2 Evaluation of the network 154

5.3.3 Effect of varying assumptions about key factors 157

6 Evaluation given crime level propositions 159

6.1 Material found on a crime scene: A general approach 159

6.1.1 Generic network construction for single offender 159

6.1.2 Evaluation of the network 161

6.1.3 Extending the single-offender scenario 163

6.1.4 Multiple offenders 166

6.1.5 The role of the relevant population 168

6.2 Findings with more than one component: The example of marks 168

6.2.1 General considerations 168

6.2.2 Adding further propositions 169

6.2.3 Derivation of the likelihood ratio 170

6.2.4 Consideration of distinct components 172

6.2.5 An extension to firearm examinations 177

6.2.6 A note on the likelihood ratio 181

6.3 Scenarios with more than one trace: ‘Two stain-one offender’ cases 182

6.4 Material found on a person of interest 185

6.4.1 General form 185

6.4.2 Extending the numerator 187

6.4.3 Extending the denominator 189

6.4.4 Extended form of the likelihood ratio 190

6.4.5 Network construction and examples 190

7 Evaluation of DNA profiling results 196

7.1 DNA likelihood ratio 196

7.2 Network approaches to the DNA likelihood ratio 198

7.2.1 The ‘match’ approach 198

7.2.2 Representation of individual alleles 198

7.2.3 Alternative representation of a genotype 202

7.3 Missing suspect 203

7.4 Analysis when the alternative proposition is that a brother of the suspect left the crime stain 206

7.4.1 Revision of probabilities and networks 206

7.4.2 Further considerations on conditional genotype probabilities 212

7.5 Interpretation with more than two propositions 214

7.6 Evaluation with more than two propositions 217

7.7 Partially corresponding profiles 220

7.8 Mixtures 223

7.8.1 Considering multiple crime stain contributors 223

7.8.2 Bayesian network for a three-allele mixture scenario 225

7.9 Kinship analyses 227

7.9.1 A disputed paternity 227

7.9.2 An extended paternity scenario 230

7.9.3 A case of questioned maternity 232

7.10 Database search 234

7.10.1 Likelihood ratio after database searching 234

7.10.2 An analysis focussing on posterior probabilities 237

7.11 Probabilistic approaches to laboratory error 241

7.11.1 Implicit approach to typing error 241

7.11.2 Explicit approach to typing error 243

7.12 Further reading 246

7.12.1 A note on object-oriented Bayesian networks 246

7.12.2 Additional topics 246

8 Aspects of combining evidence 249

8.1 Introduction 249

8.2 A difficulty in combining evidence: The ‘problem of conjunction’ 250

8.3 Generic patterns of inference in combining evidence 252

8.3.1 Preliminaries 252

8.3.2 Dissonant evidence: Contradiction and conflict 252

8.3.3 Harmonious evidence: Corroboration and convergence 256

8.3.4 Drag coefficient 261

8.4 Examples of the combination of distinct items of evidence 262

8.4.1 Handwriting and fingermarks 262

8.4.2 Issues in DNA analyses 266

8.4.3 One offender and two corresponding traces 267

8.4.4 Firearms and gunshot residues 271

8.4.5 Comments 279

9 Networks for continuous models 281

9.1 Random variables and distribution functions 281

9.1.1 Normal distribution 283

9.1.2 Bivariate Normal distribution 287

9.1.3 Conditional expectation and variance 288

9.2 Samples and estimates 289

9.2.1 Summary statistics 289

9.2.2 The Bayesian paradigm 291

9.3 Continuous Bayesian networks 292

9.3.1 Propagation in a continuous Bayesian network 295

9.3.2 Background data 300

9.3.3 Intervals for a continuous entity 302

9.4 Mixed networks 306

9.4.1 Bayesian network for a continuous variable with a discrete parent 308

9.4.2 Bayesian network for a continuous variable with a continuous parent and a binary parent, unmarried 310

10 Pre-assessment 314

10.1 Introduction 314

10.2 General elements of pre-assessment 315

10.3 Pre-assessment in a fibre case: A worked through example 316

10.3.1 Preliminaries 316

10.3.2 Propositions and relevant events 317

10.3.3 Expected likelihood ratios 319

10.3.4 Construction of a Bayesian network 321

10.4 Pre-assessment in a cross-transfer scenario 321

10.4.1 Bidirectional transfer 321

10.4.2 A Bayesian network for a pre-assessment of a cross-transfer scenario 324

10.4.3 The value of the findings 325

10.5 Pre-assessment for consignment inspection 328

10.5.1 Inspecting small consignments 328

10.5.2 Bayesian network for inference about small consignments 330

10.5.3 Pre-assessment for inspection of small consignments 333

10.6 Pre-assessment for gunshot residue particles 335

10.6.1 Formation and deposition of gunshot residue particles 335

10.6.2 Bayesian network for grouped expected findings (GSR counts) 336

10.6.3 Examples for GSR count pre-assessment using a Bayesian network 339

11 Bayesian decision networks 343

11.1 Decision making in forensic science 343

11.2 Examples of forensic decision analyses 344

11.2.1 Deciding about whether or not to perform a DNA analysis 344

11.2.2 Probability assignment as a question of decision making 352

11.2.3 Decision analysis for consignment inspection 357

11.2.4 Decision after database searching 366

11.3 Further readings 368

12 Object-oriented networks 370

12.1 Object orientation 370

12.2 General elements of object-oriented networks 371

12.2.1 Static versus dynamic networks 371

12.2.2 Dynamic Bayesian networks as object-oriented networks 373

12.2.3 Refining internal class descriptions 374

12.3 Object-oriented networks for evaluating DNA profiling results 378

12.3.1 Basic disputed paternity case 378

12.3.2 Useful class networks for modelling kinship analyses 379

12.3.3 Object-oriented networks for kinship analyses 381

12.3.4 Object-oriented networks for inference of source 383

12.3.5 Refining internal class descriptions and further considerations 385

13 Qualitative, sensitivity and conflict analyses 388

13.1 Qualitative probability models 389

13.1.1 Qualitative influence 389

13.1.2 Additive synergy 392

13.1.3 Product synergy 394

13.1.4 Properties of qualitative relationships 396

13.1.5 Implications of qualitative graphical models 401

13.2 Sensitivity analyses 402

13.2.1 Preliminaries 402

13.2.2 Sensitivity to a single probability assignment 403

13.2.3 Sensitivity to two probability assignments 405

13.2.4 Sensitivity to prior distribution 408

13.3 Conflict analysis 410

13.3.1 Conflict detection 411

13.3.2 Tracing a conflict 414

13.3.3 Conflict resolution 415

References 419

Author index 433

Subject index 438

English

“The clear and accessible style of this second edition makes this book ideal for all forensic scientists, applied statisticians and graduate students wishing to evaluate forensic  findings from the perspective of probability and decision analysis. It will also appeal to lawyers and other scientists and professionals interested in the evaluation and interpretation of forensic findings, including decision making based on scientific information.”  (Zentralblatt MATH, 1 October 2014)

 

loading