Appendix 4B Binomial tree option valuation functions 89
Exercises on writing functions 94
Solution notes for exercises on functions 95
Part Two Equities 99
5 Introduction to equities 101
6 Portfolio optimisation 103
6.1 Portfolio mean and variance 103
6.2 Risk–return representation of portfolios 105
6.3 Using Solver to find efficient points 106
6.4 Generating the efficient frontier (Huang and Litzenberger’s approach) 109
6.5 Constrained frontier portfolios 111
6.6 Combining risk-free and risky assets 113
6.7 Problem One–combining a risk-free asset with a risky asset 114
6.8 Problem Two–combining two risky assets 115
6.9 Problem Three–combining a risk-free asset with a risky portfolio 117
6.10 User-defined functions in Module1 119
6.11 Functions for the three generic portfolio problems in Module1 120
6.12 Macros in ModuleM 121
Summary 123
References 123
7 Asset pricing 125
7.1 The single-index model 125
7.2 Estimating beta coefficients 126
7.3 The capital asset pricing model 129
7.4 Variance–covariance matrices 130
7.5 Value-at-Risk 131
7.6 Horizon wealth 134
7.7 Moments of related distributions such as normal and lognormal 136
7.8 User-defined functions in Module1 136
Summary 138
References 138
8 Performance measurement and attribution 139
8.1 Conventional performance measurement 140
8.2 Active–passive management 141
8.3 Introduction to style analysis 144
8.4 Simple style analysis 145
8.5 Rolling-period style analysis 146
8.6 Confidence intervals for style weights 148
8.7 User-defined functions in Module1 151
8.8 Macros in ModuleM 151
Summary 152
References 153
Part Three Options on Equities 155
9 Introduction to options on equities 157
9.1 The genesis of the Black–Scholes formula 158
9.2 The Black–Scholes formula 158
9.3 Hedge portfolios 159
9.4 Risk-neutral valuation 161
9.5 A simple one-step binomial tree with risk-neutral valuation 162
9.6 Put–call parity 163
9.7 Dividends 163
9.8 American features 164
9.9 Numerical methods 164
9.10 Volatility and non-normal share returns 165
Summary 165
References 166
10 Binomial trees 167
10.1 Introduction to binomial trees 167
10.2 A simplified binomial tree 168
10.3 The Jarrow and Rudd binomial tree 170
10.4 The Cox, Ross and Rubinstein tree 173
10.5 Binomial approximations and Black–Scholes formula 175
10.6 Convergence of CRR binomial trees 176
10.7 The Leisen and Reimer tree 177
10.8 Comparison of CRR and LR trees 178
10.9 American options and the CRR American tree 180
10.10 User-defined functions in Module0 and Module1 182
Summary 183
References 184
11 The Black–Scholes formula 185
11.1 The Black–Scholes formula 185
11.2 Black–Scholes formula in the spreadsheet 186
11.3 Options on currencies and commodities 187
11.4 Calculating the option’s ‘greek’ parameters 189
11.5 Hedge portfolios 190
11.6 Formal derivation of the Black–Scholes formula 192
11.7 User-defined functions in Module1 194
Summary 195
References 196
12 Other numerical methods for European options 197
12.1 Introduction to Monte Carlo simulation 197
12.2 Simulation with antithetic variables 199
12.3 Simulation with quasi-random sampling 200
12.4 Comparing simulation methods 202
12.5 Calculating greeks in Monte Carlo simulation 203
12.6 Numerical integration 203
12.7 User-defined functions in Module1 205
Summary 207
References 207
13 Non-normal distributions and implied volatility 209
13.1 Black–Scholes using alternative distributional assumptions 209
13.2 Implied volatility 211
13.3 Adapting for skewness and kurtosis 212
13.4 The volatility smile 215
13.5 User-defined functions in Module1 217
Summary 219
References 220
Part Four Options on Bonds 221
14 Introduction to valuing options on bonds 223
14.1 The term structure of interest rates 224
14.2 Cash flows for coupon bonds and yield to maturity 225
14.3 Binomial trees 226
14.4 Black’s bond option valuation formula 227
14.5 Duration and convexity 228
14.6 Notation 230
Summary 230
References 230
15 Interest rate models 231
15.1 Vasicek’s term structure model 231
15.2 Valuing European options on zero-coupon bonds, Vasicek’s model 234
15.3 Valuing European options on coupon bonds, Vasicek’s model 235
15.4 CIR term structure model 236
15.5 Valuing European options on zero-coupon bonds, CIR model 237
15.6 Valuing European options on coupon bonds, CIR model 238
15.7 User-defined functions in Module1 239
Summary 240
References 241
16 Matching the term structure 243
16.1 Trees with lognormally distributed interest rates 243
16.2 Trees with normal interest rates 246
16.3 The Black, Derman and Toy tree 247
16.4 Valuing bond options using BDT trees 248
16.5 User-defined functions in Module1 250
Summary 252
References 252
Appendix Other VBA functions 253
Forecasting 253
ARIMA modelling 254
Splines 256
Eigenvalues and eigenvectors 257
References 258
Index 259
DESCRIPTION This new and unique book demonstrates that Excel and VBA can play an important role in the explanation and implementation of numerical methods across finance. Advanced Modelling in Finance provides a comprehensive look at equities, options on equities and options on bonds from the early 1950s to the late 1990s. The book adopts a step-by-step approach to understanding the more sophisticated aspects of Excel macros and VBA programming, showing how these programming techniques can be used to model and manipulate financial data, as applied to equities, bonds and options. The book is essential for financial practitioners who need to develop their financial modelling skill sets as there is an increase in the need to analyse and develop ever more complex 'what if' scenarios.
9780471499220
Finance--Mathematical models Microsoft Excel (Computer file) Microsoft Visual Basic for applications Visual Basic (Computer program language)