Basic Stochastic Processes

Basic Stochastic Processes

Devolder, Pierre
Janssen, Jacques
Manca, Rainmondo

113,05 €(IVA inc.)

This book presents basic stochastic processes, stochastic calculus including Lévy processes on one hand, and Markov and Semi Markov models on the other. From the financial point of view, essential concepts such as the Black and Scholes model, VaR indicators, actuarial evaluation, market values, fair pricing play a central role and will be presented. The authors also present basic concepts so that this series is relatively self–contained for the main audience formed by actuaries and particularly with ERM (enterprise risk management) certificates, insurance risk managers, students in Master in mathematics or economics and people involved in Solvency II for insurance companies and in Basel II and III for banks. INDICE: INTRODUCTION  xi .CHAPTER 1. BASIC PROBABILISTIC TOOLS FOR STOCHASTIC MODELING  1 .1.1. Probability space and random variables  1 .1.2. Expectation and independence 4 .1.3. Main distribution probabilities 7 .1.3.1. Binomial distribution 7 .1.3.2. Negative exponential distribution 8 .1.3.3. Normal (or Laplace Gauss) distribution 8 .1.3.4. Poisson distribution 11 .1.3.5. Lognormal distribution 11 .1.3.6. Gamma distribution 12 .1.3.7. Pareto distribution  13 .1.3.8. Uniform distribution 16 .1.3.9. Gumbel distribution 16 .1.3.10. Weibull distribution 16 .1.3.11. Multi–dimensional normal distribution 17 .1.3.12. Extreme value distribution 19 .1.4. The normal power (NP) approximation  28 .1.5. Conditioning  31 .1.6. Stochastic processes  39 .1.7. Martingales 43 .CHAPTER 2. HOMOGENEOUS AND NON–HOMOGENEOUS RENEWAL MODELS 47 .2.1. Introduction 47 .2.2. Continuous time non–homogeneous convolutions  49 .2.2.1. Non–homogeneous convolution product 49 .2.3. Homogeneous and non–homogeneous renewal processes  53 .2.4. Counting processes and renewal functions  56 .2.5. Asymptotical results in the homogeneous case  61 .2.6. Recurrence times in the homogeneous case  63 .2.7. Particular case: the Poisson process  66 .2.7.1. Homogeneous case  66 .2.7.2. Non–homogeneous case 68 .2.8. Homogeneous alternating renewal processes 69 .2.9. Solution of non–homogeneous discrete timevevolution equation 71 .2.9.1. General method  71 .2.9.2. Some particular formulas  73 .2.9.3. Relations between discrete time and continuous time renewal equations  74 .CHAPTER 3. MARKOV CHAINS  77 .3.1. Definitions 77 .3.2. Homogeneous case  78 .3.2.1. Basic definitions 78 .3.2.2. Markov chain state classification  81 .3.2.3. Computation of absorption probabilities 87 .3.2.4. Asymptotic behavior 88 .3.2.5. Example: a management problem in an insurance company  93 .3.3. Non–homogeneous Markov chains 95 .3.3.1. Definitions 95 .3.3.2. Asymptotical results 98 .3.4. Markov reward processes  99 .3.4.1. Classification and notation 99 .3.5. Discrete time Markov reward processes (DTMRWPs)  102 .3.5.1. Undiscounted case  102 .3.5.2. Discounted case  105 .3.6. General algorithms for the DTMRWP 111 .3.6.1. Homogeneous MRWP  112 .3.6.2. Non–homogeneous MRWP 112 .CHAPTER 4. HOMOGENEOUS AND NON–HOMOGENEOUS SEMI–MARKOV MODELS  113 .4.1. Continuous time semi–Markov processes 113 .4.2. The embedded Markov chain  117 .4.3. The counting processes and the associated semi–Markov process  118 .4.4. Initial backward recurrence times  120 .4.5. Particular cases of MRP 122 .4.5.1. Renewal processes and Markov chains  122 .4.5.2. MRP of zero–order (PYKE (1962))  122 .4.5.3. Continuous Markov processes 124 .4.6. Examples  124 .4.7. Discrete time homogeneous and non–homogeneous semi–Markov processes  127 .4.8. Semi–Markov backward processes in discrete time 129 .4.8.1. Definition in the homogeneous case  129 .4.8.2. Semi–Markov backward processes in discrete time for the non–homogeneous case 130 .4.8.3. DTSMP numerical solutions  133 .4.9. Discrete time reward processes 137 .4.9.1. Undiscounted SMRWP 137 .4.9.2. Discounted SMRWP 141 .4.9.3. General algorithms for DTSMRWP  144 .4.10. Markov renewal functions in the homogeneous case  146 .4.10.1. Entrance times  146 .4.10.2. The Markov renewal equation  150 .4.10.3. Asymptotic behavior of an MRP 151 .4.10.4. Asymptotic behavior of SMP 153 .4.11. Markov renewal equations for the non–homogeneous case  158 .4.11.1. Entrance time  158 .4.11.2. The Markov renewal equation  162 .CHAPTER 5. STOCHASTIC CALCULUS  165 .5.1. Brownian motion 165 .5.2. General definition of the stochastic integral  167 .5.2.1. Problem of stochastic integration 167 .5.2.2. Stochastic integration of simple predictable processes and semi–martingales 168 .5.2.3. General definition of the stochastic integral 170 .5.3. Itô s formula  177 .5.3.1. Quadratic variation of a semi–martingale 177 .5.3.2. Itô s formula  179 .5.4. Stochastic integral with standard Brownian motion as an integrator process  180 .5.4.1. Case of simple predictable processes 181 .5.4.2. Extension to general integrator processes 183 .5.5. Stochastic differentiation 184 .5.5.1. Stochastic differential  184 .5.5.2. Particular cases  184 .5.5.3. Other forms of Itô s formula  185 .5.6. Stochastic differential equations  191 .5.6.1. Existence and unicity general theorem  191 .5.6.2. Solution of stochastic differential equations 195 .5.6.3. Diffusion processes  199 .5.7. Multidimensional diffusion processes 202 .5.7.1. Definition of multidimensional Itô and diffusion processes  203 .5.7.2. Properties of multidimensional diffusion processes  203 .5.7.3. Kolmogorov equations  205 .5.7.4. The Stroock Varadhan martingale characterization of diffusion processes  208 .5.8. Relation between the resolution of PDE and SDE problems. .The Feynman Kac formula  209 .5.8.1. Terminal payoff  209 .5.8.2. Discounted payoff function 210 .5.8.3. Discounted payoff function and payoff rate 210 .5.9. Application to option theory 213 .5.9.1. Options 213 .5.9.2. Black and Scholes model . 216 .5.9.3. The Black and Scholes partial differential equation (BSPDE) and the BS formula  216 .5.9.4. Girsanov theorem 219 .5.9.5. The risk–neutral measure and the martingale property 221 .5.9.6. The risk–neutral measure and the evaluation of derivative products  224 .CHAPTER 6. LÉVY PROCESSES  227 .6.1. Notion of characteristic functions  227 .6.2. Lévy processes 228 .6.3. Lévy Khintchine formula  230 .6.4. Subordinators  234 .6.5. Poisson measure for jumps  234 .6.5.1. The Poisson random measure  234 .6.5.2. The compensated Poisson process 235 .6.5.3. Jump measure of a Lévy process  236 .6.5.4. The Itô Lévy decomposition  236 .6.6. Markov and martingale properties of Lévy processes  237 .6.6.1. Markov property 237 .6.6.2. Martingale properties  239 .6.6.3. Itô formula 240 .6.7. Examples of Lévy processes 240 .6.7.1. The lognormal process: Black and Scholes process 240 .6.7.2. The Poisson process 241 .6.7.3. Compensated Poisson process 242 .6.7.4. The compound Poisson process  242 .6.8. Variance gamma (VG) process 244 .6.8.1. The gamma distribution 244 .6.8.2. The VG distribution 245 .6.8.3. The VG process  246 .6.8.4. The Esscher transformation 247 .6.8.5. The Carr Madan formula for the European call 249 .6.9. Hyperbolic Lévy processes 250 .6.10. The Esscher transformation  252 .6.10.1. Definition 252 .6.10.2. Option theory with hyperbolic Lévy processes  253 .6.10.3. Value of the European option call  255 .6.11. The Brownian Poisson model with jumps  256 .6.11.1. Mixed arithmetic Brownian Poisson and geometric Brownian Poisson processes 256 .6.11.2. Merton model with jumps 258 .6.11.3. Stochastic differential equation (SDE) for mixed arithmetic Brownian Poisson and geometric Brownian Poisson processes 261 .6.11.4. Value of a European call for the lognormal Merton model 264 .6.12. Complete and incomplete markets  264 .6.13. Conclusion  265 .CHAPTER 7. ACTUARIAL EVALUATION, VAR AND STOCHASTIC INTEREST RATE MODELS 267 .7.1. VaR technique 267 .7.2. Conditional VaR value  271 .7.3. Solvency II 276 .7.3.1. The SCR indicator  276 .7.3.2. Calculation of MCR 278 .7.3.3. ORSA approach  279 .7.4. Fair value  280 .7.4.1. Definition 280 .7.4.2. Market value of financial flows  281 .7.4.3. Yield curve 281 .7.4.4. Yield to maturity for a financial investment and a bond 283 .7.5. Dynamic stochastic time continuous time model for instantaneous interest rate 284 .7.5.1. Instantaneous deterministic interest rate 284 .7.5.2. Yield curve associated with a deterministic instantaneous interest rate  285 .7.5.3. Dynamic stochastic continuous time model for instantaneous interest rate  286 .7.5.4. The OUV stochastic model 287 .7.5.5. The CIR model  289 .7.6. Zero–coupon pricing under the assumption of no arbitrage 292 .7.6.1. Stochastic dynamics of zero–coupons 292 .7.6.2. The CIR process as rate dynamic 295 .7.7. Market evaluation of financial flows  298 .BIBLIOGRAPHY 301 .INDEX 309

  • ISBN: 978-1-84821-882-6
  • Editorial: ISTE Ltd.
  • Encuadernacion: Cartoné
  • Páginas: 326
  • Fecha Publicación: 04/08/2015
  • Nº Volúmenes: 1
  • Idioma: Inglés