Tài liệu về tài chính - shreve.
Steven Shreve: Stochastic Calculus and FinancePRASADCHALASANICarnegie Mellon Universitychal@cs.cmu.eduSOMESHJHACarnegie Mellon Universitysjha@cs.cmu.eduTHIS IS A DRAFT: PLEASE DO NOT DISTRIBUTEcCopyright; Steven E. Shreve, 1996July 25, 1997 Contents1 Introduction to Probability Theory 111.1 TheBinomialAssetPricingModel 111.2 Finite Probability Spaces . 161.3 LebesgueMeasureandtheLebesgueIntegral 221.4 General Probability Spaces 301.5 Independence . 401.5.1 Independenceofsets . 401.5.2 Independence of-algebras . 411.5.3 Independence of random variables 421.5.4 Correlationandindependence 441.5.5 Independenceandconditionalexpectation. . 451.5.6 LawofLargeNumbers 461.5.7 CentralLimitTheorem 472 Conditional Expectation 492.1 ABinomialModelforStockPriceDynamics 492.2 Information 502.3 ConditionalExpectation . 522.3.1 Anexample 522.3.2 Definition of Conditional Expectation 532.3.3 FurtherdiscussionofPartialAveraging . 542.3.4 PropertiesofConditionalExpectation 552.3.5 ExamplesfromtheBinomialModel . 572.4 Martingales 581 23 Arbitrage Pricing 593.1 BinomialPricing . 593.2 Generalone-stepAPT . 603.3 Risk-Neutral Probability Measure 613.3.1 PortfolioProcess . 623.3.2 Self-financing Value of a Portfolio Process 623.4 Simple European Derivative Securities 633.5 TheBinomialModelisComplete . 644 The Markov Property 674.1 BinomialModelPricingandHedging 674.2 ComputationalIssues . 694.3 MarkovProcesses . 704.3.1 DifferentwaystowritetheMarkovproperty 704.4 ShowingthataprocessisMarkov 734.5 ApplicationtoExoticOptions 745 Stopping Times and American Options 775.1 AmericanPricing . 775.2 ValueofPortfolioHedginganAmericanOption . 795.3 Information up to a Stopping Time 816 Properties of American Derivative Securities 856.1 Theproperties . 856.2 ProofsoftheProperties 866.3 Compound European Derivative Securities 886.4 OptimalExerciseofAmericanDerivativeSecurity 897 Jensen’s Inequality 917.1 Jensen’s Inequality for Conditional Expectations . 917.2 OptimalExerciseofanAmericanCall 927.3 Stopped Martingales . 948 Random Walks 978.1 FirstPassageTime 97 38.2isalmostsurelyfinite 978.3 The moment generating function for 998.4 Expectation of 1008.5 TheStrongMarkovProperty . 1018.6 GeneralFirstPassageTimes . 1018.7 Example:PerpetualAmericanPut 1028.8 DifferenceEquation 1068.9 DistributionofFirstPassageTimes 1078.10TheReflectionPrinciple . 1099 Pricing in terms of Market Probabilities: The Radon-Nikodym Theorem. 1119.1 Radon-Nikodym Theorem 1119.2 Radon-Nikodym Martingales . . . 1129.3 TheStatePriceDensityProcess . 1139.4 Stochastic Volatility Binomial Model . 1169.5 Another Applicaton of the Radon-Nikodym Theorem . . 11810 Capital Asset Pricing 11910.1AnOptimizationProblem . 11911 General Random Variables 12311.1 Law of a Random Variable 12311.2 Density of a Random Variable . . 12311.3Expectation 12411.4 Two random variables . 12511.5MarginalDensity . 12611.6ConditionalExpectation . 12611.7ConditionalDensity 12711.8MultivariateNormalDistribution . 12911.9Bivariatenormaldistribution . 13011.10MGF of jointly normal random variables . 13012 Semi-Continuous Models 13112.1Discrete-timeBrownianMotion . 131 412.2TheStockPriceProcess 13212.3RemainderoftheMarket . 13312.4Risk-NeutralMeasure . 13312.5Risk-NeutralPricing . 13412.6Arbitrage . 13412.7StalkingtheRisk-NeutralMeasure 13512.8PricingaEuropeanCall 13813 Brownian Motion 13913.1 Symmetric Random Walk . 13913.2TheLawofLargeNumbers 13913.3CentralLimitTheorem 14013.4 Brownian Motion as a Limit of Random Walks . 14113.5BrownianMotion . 14213.6CovarianceofBrownianMotion . 14313.7Finite-DimensionalDistributionsofBrownianMotion 14413.8 Filtration generated by a Brownian Motion 14413.9MartingaleProperty 14513.10TheLimitofaBinomialModel 14513.11StartingatPointsOtherThan0 14713.12MarkovPropertyforBrownianMotion 14713.13Transition Density . 14913.14FirstPassageTime 14914 The Itˆo Integral 15314.1BrownianMotion . 15314.2FirstVariation . 15314.3QuadraticVariation 15514.4 Quadratic Variation as Absolute Volatility 15714.5 Construction of the ItˆoIntegral 15814.6 Itˆointegralofanelementaryintegrand 15814.7 Properties of the Itˆointegralofanelementaryprocess 15914.8 Itˆointegralofageneralintegrand . 162 514.9 Properties of the (general) Itˆointegral 16314.10Quadratic variation of an Itˆointegral . 16515 Itˆo’s Formula 16715.1 Itˆo’sformulaforoneBrownianmotion 16715.2 Derivation of Itˆo’sformula 16815.3GeometricBrownianmotion . 16915.4QuadraticvariationofgeometricBrownianmotion . 17015.5 Volatilityof Geometric Brownian motion 17015.6FirstderivationoftheBlack-Scholesformula 17015.7MeanandvarianceoftheCox-Ingersoll-Rossprocess 17215.8 Multidimensional Brownian Motion . 17315.9Cross-variationsofBrownianmotions 17415.10Multi-dimensional Itˆoformula 17516 Markov processes and the Kolmogorov equations 17716.1StochasticDifferentialEquations . 17716.2MarkovProperty . 17816.3 Transition density . 17916.4 The Kolmogorov Backward Equation 18016.5ConnectionbetweenstochasticcalculusandKBE 18116.6Black-Scholes . 18316.7 Black-Scholes with price-dependent volatility 18617 Girsanov’s theorem and the risk-neutral measure 18917.1 Conditional expectations underfIP 19117.2Risk-neutralmeasure . 19318 Martingale Representation Theorem 19718.1MartingaleRepresentationTheorem . 19718.2Ahedgingapplication . 19718.3d-dimensionalGirsanovTheorem 19918.4d-dimensionalMartingaleRepresentationTheorem . 20018.5 Multi-dimensional market model . 200 619 A two-dimensional market model 20319.1 Hedging when,1 1 20419.2 Hedging when =1 . 20520 Pricing Exotic Options 20920.1ReflectionprincipleforBrownianmotion 20920.2UpandoutEuropeancall. 21220.3Apracticalissue 21821 Asian Options 21921.1Feynman-KacTheorem 22021.2Constructingthehedge 22021.3PartialaveragepayoffAsianoption 22122 Summary of Arbitrage Pricing Theory 22322.1Binomialmodel,HedgingPortfolio . 22322.2 Setting up the continuous model . 22522.3Risk-neutralpricingandhedging . 22722.4Implementationofrisk-neutralpricingandhedging . 22923 Recognizing a Brownian Motion 23323.1 Identifying volatility and correlation . 23523.2Reversingtheprocess . 23624 An outside barrier option 23924.1Computingtheoptionvalue 24224.2ThePDEfortheoutsidebarrieroption 24324.3Thehedge . 24525 American Options 24725.1PreviewofperpetualAmericanput 24725.2FirstpassagetimesforBrownianmotion:firstmethod 24725.3Driftadjustment 24925.4Drift-adjustedLaplacetransform . 25025.5Firstpassagetimes:Secondmethod . 251 725.6PerpetualAmericanput 25225.7ValueoftheperpetualAmericanput . 25625.8Hedgingtheput 25725.9PerpetualAmericancontingentclaim . 25925.10PerpetualAmericancall 25925.11Putwithexpiration 26025.12Americancontingentclaimwithexpiration . 26126 Options on dividend-paying stocks 26326.1Americanoptionwithconvexpayofffunction 26326.2Dividendpayingstock 26426.3 Hedging at timet1 26627 Bonds, forward contracts and futures 26727.1Forwardcontracts . 26927.2Hedgingaforwardcontract 26927.3Futurecontracts 27027.4Cashflowfromafuturecontract . 27227.5Forward-futurespread . 27227.6Backwardationandcontango . 27328 Term-structure models 27528.1 Computing arbitrage-free bond prices: first method . . . 27628.2Someinterest-ratedependentassets . 27628.3Terminology 27728.4Forwardrateagreement 27728.5 Recovering the interestrtfromtheforwardrate 27828.6 Computing arbitrage-free bond prices: Heath-Jarrow-Morton method 27928.7Checkingforabsenceofarbitrage 28028.8ImplementationoftheHeath-Jarrow-Mortonmodel . 28129 Gaussian processes 28529.1Anexample:BrownianMotion 28630 Hull and White model 293 830.1Fiddlingwiththeformulas 29530.2 Dynamics of the bond price 29630.3CalibrationoftheHull&Whitemodel 29730.4 Option on a bond . 29931 Cox-Ingersoll-Ross model 30331.1 Equilibriumdistribution ofrt 30631.2 Kolmogorov forward equation . . 30631.3 Cox-Ingersoll-Ross equilibrium density . 30931.4BondpricesintheCIRmodel 31031.5 Option on a bond . 31331.6DeterministictimechangeofCIRmodel . 31331.7Calibration 31531.8 Tracking down'00inthetimechangeoftheCIRmodel . 31632 A two-factor model (Duffie & Kan) 31932.1 Non-negativity ofY 32032.2 Zero-coupon bond prices . 32132.3Calibration 32333 Change of num´eraire 32533.1 Bond price as num´eraire . 32733.2 Stock price as num´eraire . 32833.3Mertonoptionpricingformula 32934 Brace-Gatarek-Musiela model 33534.1 Review of HJM under risk-neutralIP . 33534.2 Brace-Gatarek-Musiela model . . 33634.3LIBOR 33734.4ForwardLIBOR 33834.5 The dynamics ofLt; . 33834.6ImplementationofBGM . 34034.7Bondprices 34234.8 Forward LIBOR under more forward measure 343 934.9Pricinganinterestratecaplet . 34334.10Pricinganinterestratecap 34534.11CalibrationofBGM 34534.12Longrates . 34634.13Pricingaswap . 346 [...]... of S2 alone 20 Definition 1.5 Let be a nonemtpy finite set and let F be the -algebra of all subsets of Let X be a random variable on ; F The -algebra X generated by X is defined to be the collection of all sets of the form f! 2 ; X ! 2 Ag, where A is a subset of IR Let G be a sub- -algebra of F We say that X is G -measurable if every set in X is also in G Note: We normally write simply... c a; b = ,1; a b; 1 : This shows that every closed interval is Borel In addition, the closed half-lines 1 a; 1 = and n=1 ,1; a = a; a + n 1 n=1 a , n; a are Borel Half-open and half-closed intervals are also Borel, since they can be written as intersections of open half-lines and closed half-lines For example, a; b = ,1; b a; 1: Every set which contains only one real number is Borel Indeed,... more The -algebra F1 is said to contain the “information of the first toss”, which is usually called the “information up to time 1” Similarly, F2 contains the “information of CHAPTER 1 Introduction to Probability Theory 19 the first two tosses,” which is the “information up to time 2.” The -algebra F3 = F contains “full information” about the outcome of all three tosses The so-called “trivial” -algebra... nothing about ! Definition 1.3 Let be a nonempty finite set A filtration is a sequence of -algebras F0 ; F1; F2; : : :; Fn such that each -algebra in the sequence contains all the sets contained by the previous -algebra Definition 1.4 Let be a nonempty finite set and let random variable is a function mapping into IR F be the -algebra of all subsets of A Example 1.3 Let be given by (2.1) and consider the binomial... pricing and its relation to risk-neutral pricing is clearly illuminated Secondly, the model is used in practice because with a sufficient number of steps, it provides a good, computationally tractable approximation to continuous-time models Thirdly, within the binomial model we can develop the theory of conditional expectations and martingales which lies at the heart of continuous-time models With this third... CHAPTER 1 Introduction to Probability Theory 23 Definition 1.9 The Borel -algebra, denoted BIR, is the smallest -algebra containing all open intervals in IR The sets in BIR are called Borel sets Every set which can be written down and just about every set imaginable is in BIR The following discussion of this fact uses the -algebra properties developed in Problem 1.3 By definition, every open interval... a; b is in BIR, where a and b are real numbers Since BIR is a -algebra, every union of open intervals is also in BIR For example, for every real number a, the open half-line 1 a; 1 = n=1 is a Borel set, as is a; a + n 1 ,1; a = a , n; a: n=1 For real numbers a and b, the union ,1; a b; 1 is Borel Since BIR is a -algebra, every complement of a Borel set is Borel, so BIR contains... as preimages of sets in IR is: ;; ; AHH; AHT ATH ; ATT ; and sets which can be built by taking unions of these This collection of sets is a -algebra, called the -algebra generated by the random variable S2, and is denoted by S2 The information content of this -algebra is exactly the information learned by observing S2 More specifically, suppose the coin is tossed three times and you do not know the... 1T S2TH + 1 + rX1T , 1T S1T ; V2TT = 1T S2TT + 1 + rX1T , 1 T S1T : Subtracting one of these from the other and solving for mula” 1T , we obtain the “delta-hedging for- V 1T = S2 TH , V2TT ; TH , S TT 2 2 (1.12) and substituting this into either equation, we can solve for 1 ~ X1 T = 1 + r pV2TH + qV2 TT : ~ (1.13) 16 Equation (1.13), gives... determine IP for all the other sets in F Definition 1.2 Let be a nonempty set A -algebra is a collection following three properties: (i) ; 2 G, G of subsets of with the 18 (ii) If A 2 G , then its complement Ac 2 G, (iii) If A1; A2; A3; : : : is a sequence of sets in G , then 1 Ak is also in G k=1 Here are some important -algebras of subsets of the set F0 = F1 = F2 = ;; in Example 1.2: ; ;; . ............................ 32934 Brace-Gatarek-Musiela model 33534.1 Review of HJM under risk-neutralIP......................... 33534.2 Brace-Gatarek-Musiela model . . ........................... arbitrage-free bond prices: Heath-Jarrow-Morton method ........ 27928.7Checkingforabsenceofarbitrage .......................... 28028.8ImplementationoftheHeath-Jarrow-Mortonmodel.................