Ecological Methods, 4e
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  • Wiley

More About This Title Ecological Methods, 4e

English

4th edition of this classic Ecology text

  • Computational methods have largely been replaced by descriptions of the available software
  • Includes procedure information for R software and other freely available software systems
  • Now includes web references for equipment, software and detailed methodologies 

English

Peter A. Henderson, Director of Pisces Conservation, Southampton, UK.

T. R. E. Southwood, Lecturer, Department of Zoology, University of Oxford, UK.

English

Prefaces xiii

About the Companion Website xix

1 Introduction to the Study of Animal Populations 1

1.1 Population estimates 2

1.1.1 Absolute and related estimates 2

1.1.2 Relative estimates 3

1.1.3 Population indices 4

1.2 Errors and confidence 4

References 5

2 The Sampling Programme and the Measurement and Description of Dispersion 7

2.1 Preliminary sampling 7

2.1.1 Planning and fieldwork 7

2.1.2 Statistical aspects 10

2.2 The sampling programme 16

2.2.1 The number of samples per habitat unit (e.g. plant, host or puddle) 16

2.2.2 The sampling unit, its selection, size and shape 20

2.2.3 The number of samples 21

2.2.4 The pattern of sampling 24

2.2.5 The timing of sampling 26

2.3 Dispersion 27

2.3.1 Mathematical distributions that serve as models 28

2.3.2 Biological interpretation of dispersion parameters 40

2.3.3 Nearest-neighbour and related techniques: measures of population size or of the departure from randomness of the distribution 48

2.4 Sequential sampling 51

2.4.1 Sampling numbers 51

2.5 Presence or absence sampling 55

2.6 Sampling a fauna 57

2.7 Biological and other qualitative aspects of sampling 59

2.8 Jack knife and Bootstrap techniques 60

References 62

3 Absolute Population Estimates Using Capture–Recapture Experiments 77

3.1 Capture–recapture methods 78

3.1.1 Assumptions common to most methods 79

3.1.2 Estimating closed populations 86

3.1.3 Estimations for open populations 93

3.2 Methods of marking animals 103

3.2.1 Handling techniques 105

3.2.2 Release 107

3.2.3 Surface marks using paints and solutions of dyes 108

3.2.4 Dyes and fluorescent substances in powder form 112

3.2.5 Pollen 114

3.2.6 Marking formed by feeding on or absorption of dyes 114

3.2.7 Marking by injection, panjet or tattooing 116

3.2.8 External tags 116

3.2.9 Branding 117

3.2.10 Mutilation 118

3.2.11 Natural marks, parasites and genes 118

3.2.12 Rare elements 119

3.2.13 Protein marking 120

3.2.14 Radioactive isotopes 120

3.2.15 Radio and sonic tags 120

References 121

4 Absolute Population Estimates by Sampling a Unit of Habitat – Air, Plants, Plant Products and Vertebrate Hosts 139

4.1 Sampling from the air 139

4.2 Sampling apparatus 140

4.2.1 Exposed cone (Johnson–Taylor) suction trap 140

4.2.2 Enclosed cone types of suction trap including the Rothamsted 12 m trap 141

4.2.3 Rotary and other traps 143

4.3 Comparison and efficiencies of the different types of suction traps 144

4.3.1 Conversion of catch to aerial density 145

4.3.2 Conversion of density to total aerial population 146

4.4 Sampling from plants 146

4.4.1 Assessing the plant 147

4.4.2 Determining the numbers of invertebrates 147

4.4.3 The extraction of animals from herbage and debris 155

4.4.4 Methods for animals in plant tissues 163

4.4.5 Special sampling problems with animals in plant material 165

4.5 Sampling from vertebrate hosts 166

4.5.1 Sampling from living hosts 166

4.5.2 Sampling from dead hosts 169

4.5.3 Sampling from vertebrate ‘homes’ 170

References 171

5 Absolute Population Estimates by Sampling a Unit of Aquatic Habitat 183

5.1 Open water 183

5.1.1 Nets 183

5.1.2 Pumps 187

5.1.3 Water-sampling bottles 187

5.1.4 The Patalas–Schindler volume sampler 187

5.1.5 Particular methods for insects 188

5.2 Vegetation 190

5.2.1 Floating vegetation 191

5.2.2 Emergent vegetation 192

5.2.3 Submerged vegetation 194

5.3 Bottom fauna 195

5.3.1 Hand net sampling of forest litter 196

5.3.2 Sampling from under stones 197

5.3.3 The planting of removable portions of the substrate 199

5.3.4 Cylinders and boxes for delimiting an area 200

5.3.5 Trawls, bottom sledges and dredges 201

5.3.6 Grabs 205

5.3.7 Dendy inverting sampler 208

5.3.8 Box samplers and corers 209

5.3.9 Air-lift and suction devices 211

5.4 Poisons and anaesthetics used for sampling fish in rock pools and small ponds 211

References 213

6 Absolute Population Estimates by Sampling a Unit of Soil or Litter Habitat: Extraction Techniques 221

6.1 Sampling 221

6.2 Bulk staining 224

6.3 Mechanical methods of extraction 224

6.3.1 Dry sieving 224

6.3.2 Wet sieving 225

6.3.3 Soil washing and flotation 226

6.3.4 Flotation separation of plankton, meiofauna and other small animals 229

6.3.5 Separation of plant and insects by differential wetting 231

6.3.6 Centrifugation 233

6.3.7 Sedimentation 233

6.3.8 Elutriation 234

6.3.9 Sectioning 235

6.3.10 Aeration 236

6.4 Behavioural or dynamic methods 236

6.4.1 Dry extractors 237

6.4.2 Wet extractors 243

6.5 Summary of the applicability of the methods 248

References 250

7 Relative Methods of Population Measurement and the Derivation of Absolute Estimates 259

7.1 Factors affecting the size of relative estimates 259

7.1.1 The ‘phase’ of the animal 260

7.1.2 The activity of the animal 261

7.1.3 Differences in the response between species, sexes and individuals 263

7.1.4 The efficiency of the trap or searching method 264

7.2 The uses of relative methods 266

7.2.1 Measures of the availability 266

7.2.2 Indices of absolute population 266

7.2.3 Estimates of absolute population 267

7.2.4 Removal trapping or collecting 268

7.2.5 Collecting 272

7.3 Relative methods: catch per unit effort 272

7.3.1 Observation by radar 272

7.3.2 Hydroacoustic methods 273

7.3.3 Fish counters 274

7.3.4 Electric fishing 274

7.3.5 Aural detection 275

7.3.6 Exposure by plough 276

7.3.7 Collecting with a net or similar device 276

7.3.8 Visual searching and pooting 279

7.4 Relative methods: trapping 280

7.4.1 Interception traps 281

7.4.2 Flight traps combining interception and attraction 290

7.4.3 Light and other visual traps 294

7.5 Traps that attract animals by some natural stimulus or a substitute 304

7.5.1 Shelter traps 304

7.5.2 Trap host plants 305

7.5.3 Baited traps 305

7.5.4 The use of vertebrate hosts or substitutes as bait for insects 308

7.6 Using Sound 314

References 314

8 Estimates of Species Richness and Population Size Based on Signs, Products and Effects 337

8.1 Arthropod products 337

8.1.1 Exuviae 337

8.1.2 Frass 338

8.2 Vertebrate products and effects 341

8.3 Effects due to an individual insect 342

8.4 General effects: plant damage 343

8.4.1 Criteria 344

8.5 Determining the relationship between damage and insect populations 347

References 348

9 Wildlife Population Estimates by Census and Distance Measuring Techniques 355

9.1 Census methods 356

9.2 Point and line survey methods 357

9.2.1 Indices of abundance using transects 357

9.2.2 Methods based on flushing 357

9.2.3 Line transect methods: the Fourier series estimator 360

9.2.4 Point transects 365

9.3 Distance sampling software in R 365

9.4 Spatial distribution and plotless density estimators 367

9.4.1 Closest individual or distance method 367

9.4.2 Nearest-neighbour methods 368

References 369

10 Observational and Experimental Methods for the Estimation of Natality, Mortality and Dispersal 373

10.1 Natality 373

10.1.1 Fertility 373

10.1.2 Numbers entering a stage 375

10.1.3 The birth-rate from mark and recapture data 382

10.2 Mortality 382

10.2.1 Total 382

10.2.2 The death-rate from mark and recapture data 383

10.2.3 Climatic factors 383

10.2.4 Biotic factors 383

10.2.5 Experimental assessment of natural enemies 390

10.3 Dispersal 396

10.3.1 Detecting and quantifying jump dispersal 397

10.3.2 Quantifying neighbourhood dispersal 397

10.4 The measurement and description of home range and territory 410

10.4.1 The minimum convex polygon area method for estimating home range 411

10.4.2 The kernel estimation method for home range 412

10.5 The rate of colonisation of a new habitat and artificial substrates 413

10.6 The direction of migration 413

References 413

11 The Construction, Description and Analysis of Age-specific Life-tables 429

11.1 Types of life-table and the budget 429

11.2 The construction of a budget 430

11.3 Analysis of stage-frequency data 431

11.3.1 Southwood’s graphical method 432

11.3.2 Richards &Waloff’s first method 432

11.3.3 Manly’s method 434

11.3.4 Ruesink’s method 435

11.3.5 Dempster’s method 435

11.3.6 Richards &Waloff’s Second Method 436

11.3.7 Kiritani, Nakasuji & Manly’s method 437

11.3.8 Kempton’s method 438

11.3.9 The Bellows and Birley Method 439

11.4 The description of budgets and life-tables 440

11.4.1 Survivorship curves 440

11.4.2 Stock–recruitment (Moran–Ricker) curves 440

11.4.3 The life-table and life expectancy 443

11.4.4 Life and fertility tables and the net reproductive rate 444

11.4.5 Population growth rates 446

11.4.6 The calculation of r 448

11.5 The analysis of life-table data 449

11.5.1 The comparison of mortality factors within a generation 449

11.5.2 Survival and life budget analysis 451

11.5.3 Sibley’s 𝜆 contribution analysis 458

References 459

12 Age-grouping, Time-specific Life-tables and Predictive Population Models 465

12.1 Age-grouping 465

12.2 Aging young by developmental stage 466

12.3 Aging by using structures 467

12.3.1 Annelids 467

12.3.2 Crustaceans 467

12.3.3 Insects 467

12.3.4 Molluscs 472

12.3.5 Fish 473

12.3.6 Lampreys 474

12.3.7 Reptiles and amphibians 474

12.3.8 Birds 475

12.3.9 Mammals 475

12.4 Time-specific life-tables and survival rates 476

12.4.1 Physiological time 478

12.4.2 Life-table parameters 479

12.4.3 Recruitment in the field 479

12.4.4 Empirical models 479

12.4.5 Intrinsic rate models and variable life-tables 480

12.4.6 Lewis–Leslie matrices and R packages 481

References 484

13 Species Richness, Diversity and Packing 495

13.1 Diversity 496

13.1.1 Description of 𝛼- and 𝛾-diversity 497

13.1.2 Species richness 498

13.1.3 Models for the S:N relationship 505

13.1.4 Non-parametric indices of diversity 509

13.1.5 Which model or index? 512

13.1.6 Comparing communities – diversity ordering 513

13.1.7 Procedure to determine 𝛼-diversity 515

13.1.8 Determining 𝛽-diversity 517

13.2 Similarity and the comparison and classification of samples 520

13.2.1 Measures of complementarity 521

13.2.2 Similarity indices 521

13.2.3 Multivariate analysis 525

13.3 Species packing 530

13.3.1 Measurement of interspecific association 530

13.3.2 Measurement of resource utilisation 534

13.3.3 Niche size and competition coefficients 540

References 542

14 The Estimation of Productivity and the Construction of Energy Budgets 551

14.1 Estimation of standing crop 553

14.1.1 Measurement of biomass 553

14.2 Determination of energy density 554

14.3 Estimation of energy flow 555

14.4 The measurement of production 557

14.5 The measurement of feeding and assimilation 560

14.5.1 The quality of the food eaten 560

14.6 Feeding and assimilation rates 561

14.6.1 Radiotracer techniques 561

14.6.2 Gravimetric techniques 563

14.6.3 Indicator methods 564

14.6.4 Measurement of faecal output 565

14.7 The measurement of the energy loss due to respiration and metabolic process 565

14.7.1 Calorimetric 565

14.7.2 The exchange of respiratory gases 565

14.7.3 The respiratory rate 567

14.8 The energy budget, efficiencies and transfer coefficients 573

14.8.1 The energy budget of a population (or trophic level) 573

14.8.2 Energy transfer across trophic links 574

14.9 Identification of ecological pathways using stable isotopes 576

14.10 Assessment of energy and time costs of strategies 577

References 578

15 Studies at Large Spatial, Temporal and Numerical Scales and the Classification of Habitats 587

15.1 Remote sensing data from satellites 589

15.2 Remote sensing using piloted and unmanned aircraft 591

15.3 Long-term studies 592

15.3.1 Planning spatial and temporal sampling 593

15.3.2 The classification of time series 593

15.3.3 Detecting synchrony 603

15.3.4 Measuring temporal variability 603

15.3.5 Detecting break-points 604

15.4 Geographical information systems 607

15.5 Detection of density dependence in time series 608

15.5.1 Bulmer’s (1975) test 608

15.5.2 Pollard et al.’s (1987) randomisation test 609

15.5.3 Dennis and Taper’s (1994) bootstrap approach 611

15.5.4 Using a battery of approaches to detect density dependence 611

15.6 Citizen science projects 613

15.7 Ecosystem services 613

15.8 Habitat classification 614

15.8.1 Qualitative 614

15.8.2 Quantitative 616

References 617

Index 623

A colour plate section falls between pages 300 and 301

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