Accurate Approximation Formulae for Evaluating Barrier Stock Options with Discrete Dividends and the Application in Credit Risk Valuation

Accurate Approximation Formulae for Evaluating Barrier Stock Options with Discrete Dividends and the Application in Credit Risk Valuation Tian-Shyr Dai Chun-Yuan Chiu Abstract To price the stock options with discrete dividend payout reasonably and consistently the stock price falls due to dividend payout must be faithfully modeled. However this will significantly increase the mathematical difficulty since the post-dividend stock price process the stock price process after the price falls due to dividend payout no longer follows the lognormal diffusion process. Analytical pricing formulae are hard to be derived even for the simplest vanilla options. This paper approximates the discrete dividend payout by a stochastic continuous dividend yield so the post dividend stock price process can be approximated by another lognormally-diffusive stock process with a stochastic continuous payout ratio up to the exdividend date. Accurate approximation analytical pricing formulae for barrier options are derived by repeatedly applying the reflection principle. Besides our formulae can be applied to extend the applicability of the first passage model a branch of structural credit risk model. The stock price falls due to the dividend payout in the option pricing problem is analog to selling the firm s asset to finance the loan repayment or dividend payout in the first passage model. Thus our formulae can evaluate vulnerable bonds or the equity values given that the firm s future loan/dividend payments are known. Keywords: barrier option pricing first-passage model Department of Information and Finance Management Institute of Information Management and Finance National Chiao-Tung University 00 Ta Hsueh Road Hsinchu Taiwan 300 ROC. E-mail: d88006@csie.ntu.edu.tw. Tel: 886-3-57#57053. Fax: 886-3-575544. The author was supported in part by NSC grant 94-3-E-033-04 and NCTU research grant for financial engineering and risk management project. Institute of Information Management National Chiao-Tung University 00 Ta Hsueh Road Hsinchu Taiwan 300 ROC.

Introduction Black and Scholes 973 arrive at their ground-breaking option pricing formula for nondividend-paying stocks. Their option pricing model is extended to evaluate the credit risk of a defaultable firm by assuming that the firm defaults when its firm value fails to meet the debt obligation at maturity. Thus both equities and the corporate debts can be viewed as contingent claims of the firm value and their values can be evaluated by the aforementioned Black-Scholes option pricing formula see Merton 974. To deal with the dividend payout problem Merton 973 extends Black-Scholes formula by assuming that the stock pays a fixed continuous dividend yield. This assumption is used in the credit risk evaluation problem by allowing the firm to sell a fixed ratio of its asset continuously to finance the loan repayment or dividend payout see Kim et al. 993; Leland 994. However most dividends and coupon payments are paid discretely rather than continuously. Pricing stock options with discrete dividend payout seems to be first investigated in Black 975. This discrete payout setting is analog to the setting that allows the firm to discretely sell its asset to finance the loan repayment or dividend payout under the credit risk evaluation problem. Although much financial literature alternatively assumes that the firm is restricted from selling its asset see Leland 994 or is allowed to sell its asset continuously at a fixed rate see Kim et al. 993; Leland 994; Leland and Toft 996 it is not the only or even the typical situation in the real world financial markets. For example British Petroleum Plc. sold its asset to finance the spill fund demanded by the U.S. President Obama. Recent news also report that many companies like Anglo American Plc. and Potash Corp. of Saskatchewan Inc. sold their asset to meet the required dividend payments. Although this discrete payment setting might be more realistic it incurs significant mathematical difficulty since the stock price process or the firm s value process becomes much more complicated see Lando 004. Pricing stock options with discrete dividend payout has drawn a lot of attention in the literature. Frishling 00 shows that the underlying stock price processes are usually modeled in three following different ways. Model suggests that the stock price minus the present value of future dividends over the life of the option follows the lognormal diffusion process see Roll 977; Geske 979. Model suggests that the stock price plus the forward values of the dividends paid from today up to option maturity follows a lognormal diffusion process see Heath and Jarrow 988 and Musiela and Rutkowski 997. Model See http://online.wsj.com/article/sb000440574870486404575350830340543798.html for the news entitled as BP Won t Issue New Equity to Cover Spill Costs. See http://www.businessweek.com/news/00-0-7/anglo-may-resume-dividend-after-asset-salesanalysts-say.html for the news entitled as Anglo May Resume Dividend After Asset Sales Analysts Say and http://fxnonstop.com/index.php/component/content/article/4555-myart606 for the news entitled as Potash Weighs Asset Sales for Special Dividend.

3 suggests that the stock price falls with the amount of dividend paid at the exdividend date and follows the lognormal diffusion process between two exdividend dates. Frishling 00 argues that these three models are incompatible with each other and generate very different prices. In addition Frishling 00; Bender and Vorst 00; Bos and Vandermark 00 argue that only Model 3 can reflect the reality and generate consistent option prices. Except the aforementioned three models Chiras and Manaster 978 suggests that the discrete dividends can be transformed into a fixed continuous dividend yield. The stock option can then be analytically solved by Merton s formula see Merton 973. But Dai and Lyuu 009 show that the pricing results of their approach can deviate significantly from those generated by Model 3. The aforementioned observations suggest that the credit risk evaluation problem could be significantly mispriced if the aforementioned approaches except Model 3 are adopted. On the other hand pricing under Model 3 is mathematical intractable since the postdividend stock price process the stock price process after the price fall due to dividend payout is no longer log-normally distributed. Bender and Vorst 00 Bos and Vandermark 00 Vellekoop and Nieuwenhuis 006 Dai and Lyuu 009 and Dai 009 provide approximating analytical pricing formulae or efficient numerical methods for pricing vanilla options. But no announced papers derive analytical pricing formulae for pricing barrier stock options with discrete dividend payout. A barrier option is a popular exotic option whose payoff depends on whether the path of the underlying stock has reached a certain predetermined price level called barrier. The study of pricing barrier options is of special interesting since this problem is dual to the problem of credit risk evaluation under the first passage model a credit risk model that models the evolution of the firm value and forces the firm to default if its value is below a certain predefined default boundary. 3 Reiner and Rubinstein 99 derive analytical pricing formula for the barrier option given the condition that the underlying stock pays no dividend or fixed continuous dividend yield. Thus the process of the stock return can be expressed as a drifted Brownian motion and the joint density of the extreme stock price over the option life and the stock price at the option maturity date can therefore be derived by taking advantages of the reflection principle and the Girsanov s theorem. By using the risk neutral variation technique the pricing formulae can be derived with the aforementioned joint density function. Note that Reiner and Rubinstein 99 approach can not be directly extended to price barrier options with discrete dividend under Model 3 or to evaluate the equity or the corporate debt values of a defaultable firm with discrete loan or dividend payout. In addition deal with the discrete payout with the aforementioned models except 3 Note that the roles played by the stock price and the barrier in the barrier option pricing problem are analog to the roles played by the firm value and the default boundary in the first passage model. 3

Model 3 can produce unreasonable pricing results see Frishling 00. Besides Gaudenzi and Zanette 009 develop a tree model to address this pricing problem. The impact of discrete dividend is heuristically estimated by the linear interpolation method to avoid the combinatorial explosion problem due to non-recombining property of a bushy tree see Dai 009. However it seems that their pricing results oscillate drastically due to nonlinearity error problem see Figlewski and Gao 999. The major contribution of this paper is to derive accurate approximating analytical formulae for pricing barrier options with underlying stock paying discrete dividend. Numerical results suggest that our approximation pricing formulae provide accurate option pricing results. As a byproduct our option pricing formulae can be applied to evaluate the equity or the bond values of a defaultable firm with discrete payout. Numerical results also suggest that our formulae can explicitly show how the firm s payout to finance a debt s repayment influence the firm s financial status and the credit qualities of other outstanding debts. To brief our approach we first assume that the stock price St at time t under the risk-neutral probability is given by St = S0e µt+σw t where µ r 0.5σ r denotes the annual risk-free interest rate σ denotes the volatility and W t denotes the standard Brownian motion. Under Model 3 the stock pays dividend c c c 3... at exdividend dates t t t 3 respectively where t < t < t 3.... At the exdividend date t i the stock price falls by the amount γc i where the constant γ can be less than to reflect the effect of tax on dividend income. In this paper we set γ = for simplicity and any other constant γ < poses no difficulties for modifying our pricing formulae. The process of the stock return prior to exdividend date t can be expressed by the drifted Brownian motion: µt + σw t as described in Eq.. However the stock price at any time t between the exdividend dates t and t is St = S0e µt+σw t c e µt t +σw t W t and the stock return is no longer a drifted Brownian motion. To derive analytical pricing formulae we construct another lognormal diffusion process to approximate the price process in Eq.. By borrowing the idea in Dai and Lyuu 009 the effect of stock price fall c at exdividend date t can be simulated by the price-fall effect contributed by a stochastic continuous dividend yield q paid from time 0 to time t as follows: St = S0e µt +σw t c S0e µ q t +σw t. 3 Thus the stock price at any time t between the two exdividend dates t and t can be reexpressed as St = St e µt t +σw t W t = S0e µt q t +σw t. 4 4

Since q in Eq. 3 can be approximated solved by the first-order Taylor expansion as a affine function of W t the process of the stock return between the exdividend dates t and t µt q t + σw t can be approximated by a drifted Brownian motion. Let the option maturity T < t for simplicity. The joint distribution of the extreme stock price over the time interval [0 t or [t T ] and the stock price at time t or T can be solved by applying the reflection principle and Girsanov s theorem to the drifted Brownian motion µt + σw t the approximated drifted Brownian motion of µt q t +σw t. The pricing formulae can then be derived by applying the risk-neutral valuation method on these two joint distributions. Our approach can be extended to multiple dividend dates by repeating the aforemention steps to derive approximated stock return process between any two adjacent exdividend dates. The paper is organized as follows. Section introduces required financial and mathematical background knowledge. Section 3 derives mathematical properties useful for later pricing formulae derivation. Our approximation pricing formula is then derived in section 4. Experimental results given in section 5 verify the accuracy of our pricing formulae. Section 6 concludes the paper. Preliminaries Barrier Options and the First Passage Model Assume that a barrier stock option with strike K initiates at time 0 and matures at time T. The payoff of a up-and-out option at maturity is as follows: { θst θk + if S max < B payoff = 0 if S max B where A + denotes maxa 0 S max denotes the maximum underlying stock price between time 0 to time T B denotes the barrier and θ equals for call options and - for put options. Similarly the payoff of a down-and-out option at maturity is as follows: { θst θk + if S min < B payoff = 0 if S min B where S min denotes the minimum stock price between time 0 to time T. For simplicity our paper will focus on up-and-out call option and the extensions to other barrier options are straight forward. The same mathematical settings can be used to model the first passage model by redefining the symbol B as the default boundary S as the firm value T as the debt maturity and K as the debt obligation at the debt maturity. The firm value process St is assumed 5

to follow Eq. 4 where σ denotes the volatility of the firm value and c i denotes the loan repayment or dividend payout financed by selling the firm s asset at time t i. The firm defaults once its value falls below the default boundary prior to maturity date or can not meet the debt obligation at maturity date. Thus the equity value can be evaluated as a down-and-out call option on the firm value and each debt issued by the firm can be priced by treating it as a contingent claim of the firm value. The payoff of a up-and-out call depends on whether the stock price process has ever risen above the barrier over the life of this option. The stock price process has ever risen above the barrier during the time interval [0 τ] if and only if the maximum stock price during the time interval [0 τ] is greater than the barrier. The following theorem derived from the reflection principle and Girsanov s theorem see Shreve 007 can be applied to describe the joint density of the stock price at time τ and the maximum stock price during the time interval [0 τ]. Theorem. Let W t = αt + W t be a Brownian motion with a drift term αt and Mτ = max 0 t τ W t be its maximum value over a certain time interval [0 τ]. The joint density function of Mτ W τ is given by m w τ f Mτ W τ m w = πτ eαw α τ τ m w if m w + 0 otherwise. 5 The set of points m w that make density values non-zero also known as the support of a density is illustrated in Fig. a. Reiner and Rubinstein 99 derive analytical formulae for barrier options without discrete dividend payout by Theorem.. A detail explanation of their derivation is given below since the derivation of our formula takes advantage of their method. Define the stock return in Eq. µt + σw t σŵ t where the drifted Brownian motion Ŵ t µt/σ + W t. Define the maximum value of the Brownian motion ˆMτ as max 0 t τ Ŵ t. Thus the value of a up-and-out call option C can be derived as follows: { } C = e rt E ST K + { } max St<B 0 t T { } = e rt E S0e σŵ T K {S0e σŵ T KS0e σ ˆMT <B} { = e rt E S0e σŵ T K { Ŵ T k ˆMT <b} } 6 where k and b in Eq. 6 stand for ln K and ln B respectively. By substituting Eq. σ S0 σ S0 6

w w w 0 m 0 m 0 m - - - - - - 0 - - - 0 - - - 0 a Support of Eq. 5 b Integral Domain of Eq. 7 c Taking Intersection Figure : Domain of Double Integral in Eq. 8 The shadow area in Panel a denotes the support of the density function of f MT W T in Eq. 5 i.e. a set of points m w that make f MT W T m w non-zero. Panel b denotes the domain of integral in Eq. 7 which is also the support of the indicator function of Eq. 6. Panel c denotes the intersection of shadow areas in Panel a and b which is the domain of integral in Eq. 8. 5 into Eq. 6 with α = σ/µ we have C = = k k e rt S0e σw K f ˆMT Ŵ T m wdmdw 7 e rt S0e σw m w K w + T πt eαw α T T m w dmdw 8 where the domain of integral in Eq. 7 i.e. < m < b and k w < is the support of the indicator function in Eq. 6 as illustrated in Fig. b. The domain of integral in Eq. 8 is the intersection of the support of the joint density function f ˆMT Ŵ T m w and the support of indicator function { Ŵ T k ˆMT <b} as illustrated in Fig. c. In the double integral formula Eq. 8 since only f ˆMT Ŵ T m w contains the variable m f w + ˆMT Ŵ T m wdm can be evaluated first by the following lemma: Lemma. β u v v + π eαv α u v du = e αv α v π e βv β. Proof. β π eαv α v + u v = π e αv α u v du = e αv α u=β u v π u=v + e v = e αv α v e βv β π e β v. 7

By applying Lemma. Eq. 8 can be rewritten as C = e rt k S0e σw K = e rt S0e σw K k k m w w + T πt e αw α T w T πt = e rt K e w T α +αw T + K πt e w T πt + S 0 e w T α +αw+σw T S 0 πt e w T πt eαw α T T m w dm dw e w b T dw T α +αw + w b T +αw+σw T α + w b T dw. 9 In Eq. 9 each term of the integrand is of the form Le a w +a w+a 0 for some constants a 0 a a L. The following identity can convert the integrals of the aforementioned form into the cumulative distribution function CDF of the standard normal distribution: l e a x +a x+a 0 dx = π e a 4a 0 a 4a N a l m s 0 where m = a a s = a N denotes the CDF of the standard normal distribution. The detailed derivation of this identity is given in Eq. 46 in Appendix A. Thus Reiner and Rubinstein 99 pricing formula can be derived as a linear combination of tail probability values which can be evaluated by the CDF of the standard normal distribution. 3 Derivations of Useful Mathematical Properties Approximate the Post-dividend Stock Price Process with a Lognormal Diffusion Process In this section we derive lognormal diffusion processes to approximate the stock price process between two adjacent exdividend dates under Model 3. Note that the stock price process before the first exdividend date is already a lognormal diffusion process see Eq.. But the stock price process after the first exdividend date t illustrated in Eq. is no longer lognormally distributed. Our approximated process is derived by replacing the discrete dividend c paid at time t with a continuous dividend q paid from time 0 to time t as illustrated in Eq. 3 so the approximated stock price after time t can be expressed as Eq. 4. To make this process a lognormal diffusion one q is approximately solved as a linear 8

function of W t from Eq. 3 as follows: S0e µt +σw t c S0e µt +σw t q t c q t S0e µt +σw t q c e µt e σw t t S0 q c e µt σw t t S0 where the first order Taylor expansion e x + x is used in Eq. and. By substituting k c e µt q S0 k σw t t into Eq.4 we obtain the lognormal process to approximate the stock price process between time t and t as follows: St S0e µt k σw t +σw t +σw t W t = S0e µt k ++k σw t +σw t W t. 3 The aforementioned procedure can be repeated to find the lognormal diffusion process that approximate the stock price process between the exdividend dates t and t 3. Again we replace the discrete dividend c with a continuous dividend yield q paid from time t to time t ; that is St = St e µt t +σw t W t c e µt t +σw t W t = S0e µ q t +σw t e µ q t t +σw t W t e µt t +σw t W t. 4 Note that q can be approximately solved by the first-order Taylor expansion to get q k [ k σw t σw t W t ] t t 5 where k c e µt +k S0. Therefore the stock price process between exdividend dates t and t 3 can be approximated by a lognormal diffusion process by substituting Eq. 5 into Eq. 4 to get St S0e µt k k ++k k σw t +k σw t W t +σw t W t. 6 Thus the approximated stock price process Ŝt used to derive the pricing formulae later is constructed by combining Eqs. 3 and 6 as follows: S0e µt+σw t 0 t < t Ŝt = S0e µt k ++k σw t +σw t W t t t < t S0e µt k k ++k k σw t +k σw t W t +σw t W t t t < t 3. 9 7

To derive the pricing formulae with Theorem. the stock return in Eq. 7 should be reexpressed in terms of drifted Brownian motions. Let α µ/σ for convenience. First the process Ŝt for t [0 t is rewritten as S0e σŵ t 8 by substituting Ŵ t αt + W t for t [0 t into the first line of Eq. 7. The process Ŝt for t [t t is rewritten from the second line of Eq. 7 as follows: Ŝt = S0e µt k ++k σw t +σw t W t = S0e k +µt +k [µt +σw t ]+[µt t +σw t W t ] = S 0e k σŵ t +σŵt t 9 where the drifted Brownian motion Ŵt t αt t + W t W t for t [t t and S 0 S0e k +µt. The stock price process Ŝt for t [t t 3 can be further rewritten from the third line of Eq. 7 as Ŝt = S0e µt k k ++k k σw t +k σw t W t +σw t W t = S0 exp {µt k k + k k µt k µt t µt t + k k [µt + σw t ] + k [µt t + σw t W t ] + [µt t + σw t W t ]} = S 0e k k σŵ t +k σŵt t +σŵt t 0 where S 0 S0e µt k k + k k µt k µt t µt t and Ŵt t αt t +W t W t for t [t t 3. By combining Eqs. 8 9 and 0 the approximated stock price process Ŝt can be rewritten as S0e σŵ t 0 t < t Ŝt = S 0e k σŵ t +σŵt t t t < t S 0e k k σŵ t +k σŵt t +σŵt t t t < t 3. Note that the aforementioned method can be recursively applied to solve the approximated stock price process between arbitrary two adjacent exdividend dates. Evaluate the Integration of Exponential Functions Indeed most option pricing formulae including the formulae in this paper can be expressed in terms of multiple integrations of an exponential function the exponent term of which 0

is a quadratic function of integrators. Theorem 3. shows that such an integration can be expressed as a CDF of multi-variate normal distribution by taking advantages of some matrix and vector calculations. For simplicity for any matrix ℸ we use ℸ ℸ T and ℸ to denote the determinant the transpose and the inverse of ℸ. ℸ ij stands for the element located at the i-th row and j-th column of ℸ. For any vector ν we use ν i to denote the i-th element of ν. Theorem 3. Let x and B be an n constant vector C be a constant and A be an n n symmetric invertible negative-definite constant matrix. For any general quadratic formula x T Ax + B T x + C the n-variate integral for e xt Ax+B T x+c pn pn p e xt Ax+B T x+c dx can be expressed in terms of a CDF of a n-dimensional standard normal distribution F Y Y Y n with covariance matrix Σ as follows: e C π n A F Y Y Y n p m S p m S p n m n Σ 3 S nn where the vector m = m m... m n A B C C 4 BT A B Σ SAS and S is a n n diagonal matrix defined as A ii if i = j S ij 0 otherwise. Proof. See Appendix A. 4 Analytical Formulae We will first derive the approximating analytical pricing formula for the up-and-out barrier call with single discrete dividend in Sec. 4.. Our approach can be extended to derive pricing formulae for the multi-dividend case as discussed in Sec. 4.. 4. The Single-discrete-dividend Case Since only one dividend is paid during the life of the option the option maturity date T is longer than the first exdividend date t but smaller than the second exdividend date t i.e

t < T < t. The call option value Ċ can be evaluated by the risk-neutral valuation method as follows: Ċ e rt E [ ] ŜT K {Ė Ė Ė3} 4 where Ė Ė denote the events that the stock price process does not hit barrier B during time interval [0 t and [t T ] respectively and Ė3 denotes the event that stock price is greater than the strike price K at maturity date. Specifically the three events Ė Ė Ė3 are defined as follows: Ė Ė Ė 3 {Ŝt < B t [0 t } {Ŝt < B t [t T ]} } {ŜT > K. 5 To evaluate the option value we derive the joint density of the maximum stock prices over the time interval [0 t and [t T ] and the stock price at time t and T by Theorem.. Let ˆMt max 0 t<t Ŵ t be the maximum value of Ŵ t over the time interval [0 t and ˆM T t max t t T Ŵt t be the maximum value of Ŵt t over the time interval [t T ]. Thus the three events Ė Ė Ė3 can be rewritten by substituting the definition of Ŝt defined in Eq. into Eq. 5 to get Ė { } { } = S0e σ ˆMt < B = ˆMt < b Ė { } { } = S 0e k σŵ t +σ ˆM T t < B = ˆM T t < b k Ŵ t Ė 3 { } } = S 0e k σŵ t +σŵt t > K = {Ŵ T t > k k Ŵ t where b b and k represent log B log B and log K for simplicity. In addition σ S0 σ S 0 σ S 0 Theorem. says that the joint density functions f ˆMt Ŵ t and f ˆM T t ŴT t are given as follows: { f ˆMt Ŵ t m w = m w f ˆM T t ŴT t m w = t πt e αw α t t m w if m w + 0 otherwise { m w T t πt t eαw α T t T t m w if m w + 0 otherwise. For simplicity from now on we will use the symbols f 0 and f to represent f ˆMt Ŵ t and f ˆM T t ŴT t respectively. Since the two drifted Brownian motion Ŵ t for t [0 t and Ŵ t t for t [t T ] are independent due to the Markov property of Brownian motion 6 7

the joint density function of maximum stock prices over [0 t and [t T ] and the stock prices at time t and T can be calculated by directly multiplying f 0 by f. By substituting the above arguments into Eq.4 the analytical pricing formula can be derived by the law of iterated expectation as follows: [ [ ]] Ċ = e rt E E ŜT K {Ė Ė Ė3} Ŵ t ˆMt = e rt = e rt kw k k w kw kw w + k k w w + S 0e k σw+σw K f m w f 0 m wdm dw dmdw 8 S 0e k σw+σw K f m w f 0 m wdm dw dmdw 9 where the domain of integral in Eq. 9 is obtained by mimicking the analysis in Fig. ; it is derived by taking the intersection of the supports of f m w and f 0 m 0 w 0 with the integral domain in Eq. 8. Since only f 0 m w contains m and f m w contains m in the integrand in Eq. 9 f w + 0 m wdm and k w f w + m w dm can be integrated separately by Lemma. as follows: Ċ = e rt k w S 0e k σw+σw K k k w b k w m w w + T t πt t eαw α T t T t m w dm m w e αw α t m w t dm dw dw. 30 w + t πt To eliminate the variables in the lower limit and the upper limit for the integral on w we substitute x = w + k w and y = w into Eq. 30 to get 4 Ċ = e rt S 0e σx K k πt t eαx k y α T t x k y T t e e αy α t y πt = e rt t where the integrand I is defined as e y b t dxdy. b k y x k y b k y T t 3 k I + I + I3 + I4 + I5 + I6 + I7 + I8dxdy 3 K I π e T t t 4 Note that the Jacobian determinant w w xy =. y +αy+αx yk t α T t α t x yk T t 3

x b b yk T t I Ie I3 Ie y b x b b yk + t T t and I4 Ie y b t. These four terms are obtained by multiplying the strike price K in Eq. 3 with the terms in the following two lines. I5 I6 I7 and I8 which are obtained by multiplying S 0e σx in Eq. 3 with the terms in the following two lines are defined as Ii = S 0 K Ii 4eσx i = 5... 8. 33 Since each exponent term of the integrands I I I8 is a quadratic polynomial of integrators x and y the double integral of each integrand can be expressed in terms of a bivariate normal CDF by the following lemma: Corollary 4. The double integral G with the following format can be expressed in terms of the CDF of a bivariate standard normal distribution F Y Y as follows: Gp q a a a 3 a 4 a 5 a 6 q p = π exp a 6 + a a 4 a 5 a 3 a 4 a a 5 where 4a a 3 a and Σ e a x +a xy+a 3 y +a 4 x+a 5 y+a 6 dxdy p + a 3a 4 a a 5 F YY a3 a a a 3 a. a a 3 q + a a 5 a a 4 a Σ 34 Proof. It can be easily derived from Theorem 3. and is proved in Appendix B. With Corollary 4. the double integrals of I I I8 can be converted into CDFs of bivariate normal distributions. For example the integral of I can be rewritten as Idxdy = k K b = π T t t k k b e T t x + k xy T t K π e T t t e T t x + k xy T t k T t + y t +αx+α αk y T α y t +αy+αx yk α T t α t x yk k T t + y t +αx+α αk y T α dxdy dxdy T t dxdy. 35 Define a a T t k k T t a 3 + T t t a 4 α a 5 α αk a 6 T α be the coefficients of x xy y x y and the constant term respectively of the exponential term of the integrand I in Eq. 35. By Corollary 4. Eq. 35 can be 4

rewritten in terms of bivariate normal CDFs as follows: K π π exp a 6 + a a 4 a 5 a 3 a 4 a a 5 T t t b + a 3a 4 a a 5 b + a a 5 a a 4 F YY Σ a3 a F Y Y k + a3a4 aa5 a3 b + a a 5 a a 4 a Σ 36 where Σ are obtained by substituting a a a 6 into Corollary 4. as follows: 4a a 3 a Σ a a a 3 For convenience we rewrite Eq. 36 as follows: a a a 3 D[Gb b a a a 3 a 4 a 5 a 6 Gk b a a a 3 a 4 a 5 a 6 ] K where D and G is defined in Eq. 34. Similarly the double integrals for π T t t I I3... I8 in Eq. 3 can all be expressed as k Iidxdy = Di[Gb b a i a i a 3 i a 4 i a 5 i a 6 i. Gk b a i a i a 3 i a 4 i a 5 i a 6 i] where a i a i a 3 i a 4 i a 5 i and a 6 i denotes the coefficients of x xy y x y and the constant term of the exponential term of Ii. Specifically the parameters are given by a i = a a 3 i = a 3 a i = i+ a for i = 3 8 and Di a 4 i a 5 i a 6 i are given by the following table: i Di a 4 i a 5 i a 6 i K π T t t T t + α α + k T t α K 3 α π T t t t + α αk t 4 K π T t t 5 S 0 T t + α t + α + k T t α 4b +T α T α t T t t α + σ α αk T α π T t t T t + α + σ α + k T t α 6 S 0 π T t t 7 S 0 α + σ π T t t t + α αk t 8 S 0 π T t t T t + α + σ t + α + k T t α 5 T α T α T t 4b +T α T α t T t t T α T α T t

Thus the option pricing formula in Eq. 3 can be rewritten as Ċ = e rt = e rt 8 i= k I + I + + I8dxdy [ Di[Gb b a i a i a 3 i a 4 i a 5 i a 6 i ] Gk b a i a i a 3 i a 4 i a 5 i a 6 i]. Note that if the upper barrier B the up-and-out call becomes a vanilla call option. Indeed b = log B and σ S0 b = log B and our pricing formula degenerate into σ S 0 an approximating pricing formula for vanilla stock call options with one discrete dividend payout derived in Dai and Lyuu 009. 4. Multi-discrete-dividend Case The above approach can be repeatedly applied to derive approximated pricing formulae for barrier stock options with multiple discrete dividend payout. For simplicity we derive the pricing formula for the two-dividend case in this section. The extensions for three or more dividends cases are straightforward. Note that t < t < T < t 3 in the two-dividend case. To evaluate the option we need to derive the joint density function of the maximum stock prices over the time intervals [0 t [t t and [t T ] and the stock price at time T. Let ˆM t t max t t<t Ŵ t t be the maximum value of Ŵ t over the time interval [t t and ˆM T t max t t T Ŵt t be the maximum value of Ŵt over the time interval [t T ]. The joint density function of ˆM t t and Ŵt t and the density function of ˆM T t and ŴT t can be derived by applying Theorem. as follows: f ˆM t t Ŵt t m w = f ˆM T t ŴT t m w = m w t t πt t eαw α t t 0 otherwise m w T t πt t eαw α T t t t m w if m w + 0 otherwise. 37 T t m w if m w + For simplicity we use f 0 f and f to represent the density functions f ˆMt Ŵ t see Eq. 6 f ˆM t t Ŵt t and f ˆM T t ŴT t respectively. Note that the drifted Brownian motions Ŵ t for t [0 t Ŵ t t for t [t t and Ŵt t for t [t t 3 ] are independent due to the Markov property of Brownian motion the joint density function of 6 38

maximum stock prices over [0 t [t t and [t T ] and the stock prices at time t t and T can be calculated by directly multiplying f 0 with f and f. The option value can be evaluated by the risk-neutral variation method as follows: [ ] C e rt E ŜT K {Ë Ë Ë3 Ë4} 39 where Ë Ë Ë 3 represent the events that the stock price process does not hit the barrier B during the time interval [0 t [t t and [t T ] respectively and Ë4 denotes the event that the stock price at maturity is greater than the strike price. Specifically Ë Ë Ë3 and Ë 4 are defined as { } { } Ë = S0e σ ˆMt < B = ˆMt < b { } { } Ë = S 0e k σŵ t +σ ˆM t t < B = ˆM t t < b k Ŵ t { } Ë 3 = S 0e k k σŵ t +k σŵt t +σ ˆM T t < B { = ˆM T t < b k k Ŵ t k Ŵ t t } { } Ë 4 = S 0e k k σŵ t +k σŵt t +σŵt t < K = {Ŵ T t < k k k Ŵ t k Ŵ t t } where k log K and σ S b log B respectively. Thus we can compute the pricing 0 σ S 0 formula in Eq.39 by applying the law of iterated expectation as follows: [ [ [ C = e rt E E E ŜT K {Ë Ë Ë3 Ë4} ]] Ŵ t ˆMt Ŵt t ˆM t t ] Ŵ t ˆMt = e rt k w k k k w k w k k w k w S 0e k k σw+k σw +σw K f m w f m w f 0 m wdm dw dm dw dmdw 40 = e rt w + kw kw kk w k w kk w k w w + k k k w k w w + S 0e kkσw+kσw+σw K f m w f m w f 0 m wdm dw dm dw dmdw 4 where the domain of integral in Eq. 4 is obtained by by taking the intersection of the supports of f m w f m w f 0 m w with the integral domain in Eq. 40. Since only f m w contains m f m w contains m and f 0 m w contains m in the integrand in Eq. 4 f0 m wdm f m w dm and f m w dm can be simplified by applying 7

Lemma. as follows: C = e rt b k w b k k w k w k k k w k w S 0e k k σw+k σw +σw K b k k w k w m w w + T t πt t eαw α T t T t m w dm b k w m w w + t t πt t eαw α t t t t m w dm m w e αw α t m w t dm dw dw dw. w + t πt To eliminate the variables in the lower and the upper limits for the integrals on w and w we substitute x = w + k w + k k w y = w + k w and z = w into the aforementioned formula to get 5 C = e rt S 0e σx K k πt t eαx k y α T t x k y T t e πt t eαy k z α t t y k z e αz α t z πt t e z b t t t e dxdydz = e rt b k y x k y b k y T t b k z y k z b k z t t 6 k i= Jidxdydz 4 where J J J8 are defined in Table and J9 J0 J6 are defined as Ji = S 0 K Ji 8exσ i = 9... 6. Since the exponent term of each of the integrands J J J6 is a quadratic form of integrators x y and z the triple integral of each integrand can be expressed in terms of a trivariate normal CDF by the following corollary: Corollary 4. The triple integral with the following formats can be expressed in terms of a trivariate standard normal distribution F Y Y Y 3 as follows: Hp q r a a a 0 r = e C q π 3 p A F Y Y Y 3 e a x +a y +a 3 z +a 4 xy+a 5 yz+a 6 xz+a 7 x+a 8 y+a 9 z+a 0 dxdydz p m S p m S p 3 m 3 S 33 Σ 43 5 Note that the Jacobian determinant w w w xyz is. 8

Define ζ as α x yk Table : The definitions of J J... J8. 8π3 T t t t t and η as z t + αz + α y zk + α t α T t α t t J = K ζ eη J = K ζ J3 = K ζ eη+ J5 = K ζ eη+ J7 = K ζ eη+ x b b yk T t J4 = K ζ y b b zk t t J6 = K ζ x b b yk y b b zk T t + t t J8 = K ζ x yk T t y zk t t. z b t eη+ x b b yk z b t + eη+ T t y b b zk z b t + eη+ t t x b b yk y b b zk z b t + eη+ T t + t t where A = a a 4 a 6 a 4 a a 5 a 6 a 5 a 3 B = a 7 a 8 a 9 S = S 0 0 0 S 0 0 0 S 33 S jj = A jj m = A B C = a 0 4 BT A B and Σ = SAS. Proof. This corollary can be easily derived from Theorem 3.. Let a i a i a 3 i a 4 i a 5 i a 6 i a 7 i a 8 i a 9 i and a 0 i be the coefficients of x y z xy yz xz x y z and the constant term respectively of the exponential term of the integrand Ji in Table. These coefficients are listed in Appendix C. The triple integrals of Ji in Eq. 4 can be expressed in terms of CDFs of trivariate normal distributions by applying Corollary 4. as follows: k Jidxdydz = Ei[Hb b b a i a i a 0 i Hk b b a i a i a 0 i] where the function H is defined in Eq. 43 and the function Ei is defined as follows: E = E3 = E5 = E8 = E = E4 = E6 = E7 = E E9 = E = E4 = E5 = E0 = E = E3 = E6 = E9 K 8π3 T t t t t S 0 8π3 T t t t t By substituting Eq. 44 into Eq. 4 the option price formula for the two-dividend case 44 9

is derived as follows: C = e rt 6 = e rt i= k J + J + + J6dxdydz [ Ei[Hb b b a i a i a 0 i Hk b b a i a i a 0 i] 5 Numerical Results Unlike most numerical pricing approaches that will generate oscillating pricing results as mentioned in Figlewski and Gao 999 and Dai and Lyuu 00 our approximate pricing formulae can generate smooth and stable pricing results as illustrated in Fig.. In panel a the up-and-out call option value increases with the initial stock price when the initial stock price is low. However a higher initial stock price also increases the probability for the option to knock out i.e. the stock price path hits the barrier and the option values decreases with the initial stock price when the initial stock price is high. We can also observe that the delta decreases with the initial stock price in panel b. ]..5.4.3.. 48 50 5 54 a Option Value 0.5 0. 0.075 0.05 0.05-0.05-0.05 48 50 5 54 b Delta Figure : Option Value and Delta The x-axes in both panels denote the initial stock price. The risk-free rate is 3% the volatility is 0% the strike price is 50 the barrier is 65 and the time to maturity is year. A dividend is paid at 0.5 year. Panel a gives the plot of the up-and-out barrier call price against the initial stock price. Panel b gives the plot of the delta against the initial stock price. To examine the superiority of our pricing formula we will compare our approximation pricing formulae with other pricing schemes. In the following tables the pricing results in Benchmark columns are generated by the Monte Carlo simulation with 000000 paths and we use these prices as the benchmark. Ours denotes the approximation pricing formulae proposed in this paper. The discrete dividends paid over the life of the option can be 0

approximated by the equivalent continuous dividend yield q see Chiras and Manaster 978 defined as follows: n S0e qt = S0 c i e rt i 45 where n denotes the number of dividends paid during the life of the option. Then the discrete-dividend barrier option can be approximately priced by the barrier option pricing formula with a continuous dividend yield and the pricing results generated by this approach are listed under the ContDiv columns. Besides we can follow Model see Roll 977 by assuming that the process of the net-of-dividend stock price follows a lognormal diffusion process with price at time 0 defined by i= S N 0 S0 n c i e rt i. i= Thus the discrete-dividend barrier option can be approximately priced by the barrier option pricing formula by replacing the initial stock price with S N 0. The prices generated by this approach are listed under the Model columns in the following tables. 6 Table illustrates how the changes of the initial stock prices influence the option values and the accuracy of the aforementioned three pricing formulae. Similar as Fig. a the option value increases with the increment of the initial stock price when the initial price is low. The option value then decreases with the increment of the initial stock price when the initial price is high. Our pricing formula is more accurate than the other two formulae since the maximum absolute error MAE and the root-mean-squared error RMSE are lower than those for the other two formulae. In addition the pricing errors of Model are much more significant than the errors of the other two formulae. Model produces very inaccurate results the percentage of error= 0.765 90% when the initial stock price is high say 64. 0.93 Table 3 compares the pricing results under different amount of discrete dividend payout. It can be observed that the pricing errors of both ContDiv and Model increases with the amount of dividend payout while the pricing errors of Ours are much smaller. MAE and RMSE of Ours are also smaller than those of ContDiv and Model. Table 4 illustrates the pricing results under different volatilities. Note that the value of an up-and-out call decreases as the volatility increases since a higher volatility implies a higher knock out probability. It can be also observed that MAE and RMSE of Ours are all smaller than 0 while MAE and RMSE of both ContDiv and Model are much more higher. Table 5 illustrates the impacts the change of exdividend date. By observing the Benchmark column the benchmark value 6 Frishling 00 argues that Model could incorrectly render a down-and-out barrier option worthless simply because the net-of-dividend stock price reaches the barrier when the present value of future dividends is big enough.

S0 Benchmark Ours error ContDiv error Model error 46.65.60 0.0005.4 0.04.336 0.007 48.3456.347 0.009.337 0.039.364 0.084 50.5054.506 0.008.495 0.00.547 0.0363 5.589.5796 0.0033.5767 0.006.640 0.057 54.566.557 0.0089.5598 0.0063.64 0.076 56.4389.430 0.0079.4395 0.0005.543 0.034 58..093 0.009.8 0.06.3463 0.35 60 0.964 0.906 0.0059 0.966 0.00.0700 0.536 6 0.5667 0.560 0.0065 0.5745 0.0078 0.7358 0.69 64 0.93 0.868 0.0065 0.93 0.0000 0.3697 0.765 MAE 0.0089 0.04 0.765 RMSE 0.0054 0.0093 0.09 Table : Comparing the Effect of Changing Initial Stock Prices on Pricing Barrier Calls with Single Discrete Dividend The initial stock price is listed in the first column All other numerical settings are the same as those in Fig.. The columns error list the absolute pricing error between each pricing formula and the benchmark. MAE denotes the maximum absolute error and RMSE denotes the root-mean-squared error. decreases as the time to exdividend date t increases. Our formula successfully captures this phenomenon while the other two approaches fail. Next we extend our comparison to the two-dividend case. The underlying stock is assumed to pay two dividends at year 0.5 and year and the time to maturity is set to.5 years. Table 6 illustrates the impact of changing the initial stock price and Table 7 illustrates the impact of changing the amount of dividend payout. Again MAE and RMSE of Ours are also smaller than those of ContDiv and Model. Thus we verify the superiority of our pricing formulae. Next we move our discussion to the credit risk problem. The results for pricing the vulnerable bond with face value $3000 is illustrated in Fig. 3 where x-axis denotes the bond maturity. We assume that the firm value is 5000 the volatility of the firm value is 5% an exogenously given default boundary is 400 the firm regularly pays a dividend with amount $50 by selling its asset value per.5 year and the risk-free rate is %. Note that the dividend payment weakens the financial status of the firm and increases the risk of the bond that are repayed after the exdividend date. It can be observed that the pricing results of our formula marked in solid and hollow squares catch the trend of the significant price fall of the

c Benchmark Ours error ContDiv error Model error 0.3.5759.5730 0.009.5705 0.0054.5857 0.0098 0.6.5438.5435 0.0003.5387 0.005.5680 0.04 0.9.50.59 0.0073.506 0.040.5486 0.083..4868.485 0.0053.479 0.039.573 0.0405.5.4478.4493 0.005.4390 0.0088.5044 0.0566.8.447.463 0.007.4045 0.00.4798 0.065..3843.388 0.005.3694 0.050.4538 0.0695.4.3459.3488 0.0030.3338 0.0.46 0.0804 MAE 0.0073 0.050 0.0804 RMSE 0.0036 0.0 0.053 Table 3: Comparing the Effect of Changing the Amount of Dividend on Pricing Barrier Calls with Single Discrete Dividend All settings are the same as the settings in Table except that the initial stock price is set as 50 and the dividend c is listed in the first column. vulnerable bond from 893.77 at year.5 to 885.5 at year.5. To keep analytical formula tractable many credit risk papers like Kim et al. 993 and Leland 994 heuristically assume that the firm continuously sells a predetermined ratio of its asset but the pricing results marked in solid triangles can not precisely reflect the change of firm s financial status due to the discrete payout. This heuristic assumption underprices or overprices the bond when the bond maturity is less or greater than the exdividend date. 6 Conclusions Most stock dividends are paid discretely rather than continuously. Up to now there is no announced analytical formula for pricing barrier stock options with discrete dividends and pricing these options by the formulae for continuous dividend payout could lead to unreasonable pricing results. This paper provides accurate approximating analytical formulae for pricing barrier stock option with discrete dividend payout. Numerical results are given to confirm the superiority of our formulae to other analytical formulae. Our formula can be extended the applicability of the first passage model a popular credit risk model. The stock price falls due to dividend payout is analog to selling the firms asset to finance the debt or dividend repayments. Thus our formulae can estimate the credit risk under the first passage model given that the firms future loan/dividend payments are known. 3

Volatility Benchmark Ours error ContDiv error Model error 0..0707.0756 0.0049.055 0.054.06 0.0094 0..5054.506 0.008.495 0.00.547 0.0363 0.3 0.75 0.767 0.0047 0.77 0.0043 0.7534 0.030 0.4 0.365 0.36 0.004 0.367 0.000 0.3846 0.0 0.5 0.035 0.998 0.0037 0.03 0.00 0.44 0.009 0.6 0.05 0.97 0.0007 0.09 0.0004 0.9 0.0087 0.7 0.0767 0.0764 0.0003 0.0773 0.0006 0.087 0.0060 0.8 0.056 0.05 0.004 0.058 0.0007 0.0556 0.0030 0.9 0.0366 0.0356 0.000 0.036 0.0005 0.0388 0.00.0 0.055 0.055 0.0000 0.060 0.0005 0.079 0.004 MAE 0.0079 0.099 0.389 RMSE 0.004 0.0430 0.065 Table 4: Comparing the Effect of Changing the Volatility on Pricing Barrier Calls with Single Discrete Dividend All numerical settings are the same as those settings in Table except that the initial stock price is 50 and the volatility of the stock price is listed in the first column. References Bender R. and T. Vorst 00. Options on Dividends Paying Stocks. Proceeding of the 00 International Conference on Mathematical Finance Shanghai China.. Black F. 975. Fact and Fantasy in the Use of Options. Financial Analysts Journal 3 36 4 6 7. Black F. and M. Scholes 973. The Pricing of Options and Corporate Liabilities. Journal of Political Economy 8 3 637. Bos M. and S. Vandermark 00. Finessing Fixed Dividends. Risk 5 57 58. Chiras D. and S. Manaster 978. The Informational Content of Option Prices and a Test of Market Efficiency. Journal of Financial Economics 6 3 34. Dai T.-S. 009. Efficient Option Pricing on Stocks Paying Discrete or Path-Dependent Dividends with the Stair Tree. Quantitative Finance 9 87 838. Dai T.-S. and Y. D. Lyuu 009. Accurate Approximation Formulas for Stock Options with Discrete Dividends. Applied Economics Letters 6 657 663. 4

t Benchmark Ours error ContDiv error Model error 0..545.5378 0.0047.4938 0.0486.5408 0.006 0..5347.5335 0.00.494 0.0405.540 0.0063 0.3.59.56 0.009.4945 0.0346.54 0.0 0.4.536.560 0.0076.4948 0.087.545 0.079 0.5.5054.506 0.008.495 0.00.547 0.0363 0.6.4903.486 0.004.4955 0.0053.549 0.056 0.7.4737.4658 0.0079.4958 0.0.54 0.0684 0.8.439.4399 0.0007.496 0.057.543 0.03 0.9.4036.409 0.0007.4965 0.099.545 0.389 MAE 0.0050 0.054 0.0363 RMSE 0.007 0.006 0.078 Table 5: Comparing the Effect of Changing the Exdividend Date on Pricing Barrier Calls with Single Discrete Dividend All numerical settings are the same as those settings in Table except that the initial stock price is 50 and the exdividend date is listed in the first column. Dai T.-S. and Y.-D. Lyuu 00. The Bino-trinomial Tree: A Simple Model for Efficient and Accurate Option Pricing. Journal of Deriviatives. Figlewski S. and B. Gao 999. The Adaptive Mesh Model: a New Approach to Efficient Option Pricing. Journal of Financial Economics 53 3 33 35. Frishling V. 00. A Discrete Question. Risk 5 5 6. Gaudenzi M. and A. Zanette 009. Pricing American barrier options with discrete dividends by binomial trees. Decisions in Economics and Finance 3 9 48. Geske R. 979. A Note on an Analytical Valuation Formula for Unprotected American Call Options on Stocks with Known Dividends. Journal of Financial Economics 7 4 375 380. Heath D. and R. Jarrow 988. Ex-Dividend Stock Price Behavior and Arbitrage Opportunities. Journal of Business 6 95 08. Hull J. 003. Options Futures and Other Derivatives. Prentice Hall. Kim I. K. Ramaswamy and S. Sundaresan 993. Does Default Risk in Coupons Affect the Valuation of Corporate Bonds? A Contingent Claims Model. Financial Management 3 7 3. 5

S0 Benchmark Ours error ContDiv error Model error 46 0.956 0.9 0.0034 0.9003 0.053 0.9493 0.0338 48.0033.008 0.0005 0.9964 0.0069.069 0.0586 50.0538.0493 0.0045.048 0.0058.3 0.0783 5.0484.0438 0.0046.0479 0.0005.59 0.035 54 0.9880 0.9843 0.0037 0.9934 0.0055.78 0.98 56 0.877 0.8737 0.0035 0.887 0.00.036 0.545 58 0.74 0.79 0.0049 0.7357 0.06 0.8990 0.749 60 0.5364 0.535 0.0049 0.5485 0.0 0.787 0.94 6 0.349 0.333 0.006 0.337 0.0 0.537 0.068 64 0.04 0.077 0.003 0.3 0.007 0.39 0.088 MAE 0.0049 0.053 0.088 RMSE 0.0038 0.0094 0.470 Table 6: Comparing the Effect of Changing Initial Stock Prices on Pricing Barrier Calls with Two Dividends All settings are the same as the settings in Table except that the underlying stock is assumed to pay dollar dividend at year 0.5 and year and the time to maturity is.5 years. Lando D. 004. Credit Risk Modeling: Theory and Applications. Princeton University Press. Leland H. E. 994. Corporate Debt Value Bond Covenants and Optimal Capital Structure. Journal of Finance 49 57 96. Leland H. E. and K. Toft 996. Optimal Capital Structure Endogeneous Bankruptcy and the Term Structure of Credit Spreads. Journal of Finance 5 987 09. Merton R. 973. Theory of Rational Option Pricing. Journal of Economics and Management Science 4 4 83. Merton R. 974. On the Pricing of Corporate Debt: The Risk Structure of Interest Rates. Journal of Finance 9 449 70. Musiela M. and M. Rutkowski 997. Martingale Methods in Financial Modeling. Springer. Reiner E. and M. Rubinstein 99. Breaking Down the Barriers. Risk 4 8 35. Roll R. 977 November. An analytic valuation formula for unprotected american call options on stocks with known dividends. Journal of Financial Economics 5 5 58. 6

c = c Benchmark Ours error ContDiv error Model error 0.3.305.38 0.0067.3 0.0073.54 0.00 0.6.0948.0933 0.005.093 0.005.46 0.054 0.9.0585.0606 0.00.0594 0.000.364 0.0780..079.069 0.000.048 0.003. 0.0943.5 0.9864 0.9897 0.0033 0.9885 0.00.038 0.74.8 0.955 0.9535 0.008 0.9508 0.0045.08 0.60. 0.947 0.956 0.0009 0.98 0.0030.0548 0.40.4 0.8769 0.877 0.0003 0.875 0.0055.047 0.478 MAE 0.0068 0.0073 0.478 RMSE 0.009 0.004 0.056 Table 7: Comparing the Effect of Changing the Amounts of Dividends on Pricing Barrier Calls with Two Dividends All settings are the same as the settings in Table 6 except that the initial stock price is 50 the underlying stock is assumed to pay dividend c at year 0.5 and dividend c at year. The amount of dividend payout is listed in the first column. Shreve E. 007. Stochastic Calculus for Finance II: Continuous-Time Models. Springer Finance. Vellekoop M. and J. Nieuwenhuis 006. Efficient pricing of derivatives on assets with discrete dividends. Applied Mathematical Finance 3 3. A Reexpress the Integration of Exponential Functions in terms of the CDF of Multi-Variate Normal Distribution If the price of the underlying asset is assumed to follow the lognormal diffusion process most option pricing formulae including the pricing formulae in this paper can be expressed in terms of multiple integrations of an exponential function where the exponent term is a quadratic function of integrators x x. The integration problem can be numerically solved by reexpressing the formulae in terms of CDF of Multi-Variate Normal Distribution which can be efficiently solved by accurate numerical approximation methods see Hull 003. These numerical methods are provided by mathematical softwares like Matlab and Mathemaica. Take the simplest case the single integral as an example. Under the premise 7

Figure 3: Evaluating Vulnerable Bonds. The x-axis denotes the bond maturity and the y-axis denotes the vulnerable bond price. The pricing results of our formulae are marked by solid squares. The pricing results by heuristically assuming that the firm pays a continuously payout are marked by solid triangles. a < 0 7 the integral l ea x +a x+a 0 dx can be rewritten as = l l e a x +a x+a 0 dx e x m = πe a 4a 0 a 4a = s a 4a 0 a 4a l m s π e a 4a 0 a 4a N a dx e y sdy π l m 46 s where m = a a and s = a in the second equality change of variables is applied with the equation y = x m in the third equality N in the last equality denotes the CDF of a s univariate standard normal distribution. However the integration for multivariate case is not straightforward. To address this problem we derive a general formula for the multivariate integration with n integrators: x x x n. Assume that x x x x n T is a column vector with n variables. Then the general integral formula is derived in Theorem 3. and the proof is given as follows: Proof. To express the integral in Eq. in terms of a CDF of a standard normal distribution the exponent term x T Ax + B T x + C should be expressed in terms of the exponent term of a standard normal distribution as follows: 7 The definite integral is infinite if a > 0. x T Ax + B T x + C = yt Σ y + C 47 8

where the scalar C does not depend on x. This can be achieved by applying the completing the square technique on x T Ax + B T x as discussed in the following lemma: Lemma A. Under the premises that A is a symmetric invertible n n matrix and x B are both n vectors we have x T Ax + B T x = x + T B A A x + A B 4 BT A B. 48 Proof. By expanding the right-hand side of Eq. 48 we have x + T B A A x + A B 4 BT A B = x T Ax + BT A T Ax + xt AA B + 4 BT A T AA B 4 BT A B 49 = x T Ax + BT x + xt B + 4 BT A B 4 BT A B 50 = x T Ax + B T x = the left-hand side of Eq. 48 5 where the equation A T = A due to the symmetry of A is substituted into Eq. 49. Since B T x is a scalar we have B T x = B T x T = x T B. Eq. 50 is obtained by substituting the aforementioned equalities into Eq. 49. With Lemma A. we obtain x T Ax + x T B + C = x m T Ax m + C 5 where m A B and C 47 and Eq. 5 we have C 4 BT A B. By equating the right-hand sides of Eq. x m T Ax m + C = yt Σ y + C. 53 It can be observed that y should have the form y = S x m 54 where S denotes a diagonal matrix. To solve S we first subtract C 53 to yield from both sides of Eq. x m T Ax m = yt Σ y 55 = S x m T Σ S x m 56 = x mt S Σ S x m = x mt SΣS x m 57 9

where Eq. 54 is substituted into the right-hand side of Eq. 55 S T = S due to the symmetry of S is substituted into Eq. 56. By comparing the left-hand side of Eq. 55 and Eq. 57 we have SΣS = A which can be rewritten as SΣS = A. Recall that S is a diagonal matrix. All diagonal elements of Σ are since Σ is a covariance matrix of multivariate standard normal random variables. Thus we have SΣS ii = S ii which leads us to obtain and Σ SAS. A ii if i = j S ij 0 otherwise Now we can express Eq. in terms of C m S and Σ defined above. By applying the change of variable Eq. 54 Eq. can be rewritten as = xn=pn xn =p n x n = x n = xn=pn xn =p n x n = x n = x =p x = x =p x = e xt Ax+B T x+c dx e yt Σ y+c x y dy. 58 x m T x n m n S nn the Ja- Since the elements in vector y can be represented as S x m S cobian determinant can be straightforwardly computed to get x y = n i= S ii = S. Thus Eq. 58 can be further rewritten as the following closed form formula: pn mn p n m n e C Snn S n n S = e C S Σ pn mn π n Snn = e C π n A F Y Y Y n p m S p n m n S n n p m S p m S e yt Σ y dy p m S Σ π n e yt Σ y dy 59 p n m n Σ S nn where S Σ = SΣS = A and A = n A are substituted into Eq. 59. Note that the univariate integration in Eq. 46 is a special case of this theorem. B Proof of Corollary 3. Corollary 4. can be derived from Theorem 3. by setting n = as follows: 30

First to make a x + a xy + a 3 y + a 4 x + a 5 y + a 6 equal x T Ax + x T B + C we set a a A a 4 a B C a 6. a 3 a 5 By substituting above equations into Theorem 3. we have m = a 3 a 4 a a 5 A B = 4a a 3 a a a 5 a a 4 C = C 4 BT A B = a 6 + a a 4 a 5 a 3 a 4 a a 5 4a a 3 a a S = A 3 = 4a a 3 a a S = A = 4a a 3 a a Σ = SAS = a a 3 a a a 3 A = 4a a 3 a. 4 By substituting the above into Eq. 3 we obtain q p e a x +a xy+a 3 y +a 4 x+a 5 y+a 6 dxdy π = e p m C A F Y Y q m Σ = π exp where = 4a a 3 a. S S a 6 + a a 4 a 5 a 3 a 4 a a 5 F YY p + a 3 a 4 a a 5 a3 q + a a 5 a a 4 a Σ 3

C Coefficients of the Exponential Terms of Ji The coefficients a i a i a 3 i a 4 i a 5 i and a 6 i are defined by the following formulae. a i = T t k a i = T t + t t k a 3 i = t t + t a 6 i = 0 k T t a 4 i = if i = 5 6 9 0 3 4 k T t otherwise k t a 5 i = t if i = 3 4 9 0 otherwise k t t The rest parameters are given by the following table: i a 7 i a 8 i a 9 i a 0 i α α αk α αk T α α α αk t + α αk T α t 3 T t + α α + k T t α α αk 4b +T α T α t 4 T t + α α + k 4t T b T t α t + α αk t T t 5 α t t + α αk α + k 4b t t α T α t +T α t t t 6 α t t + α αk t + α + k 4t T α t t t α +t t t t 7 T t + α t t + α + k T t α α + k t t α t t T α T t 8 T t + α t t + α + k α t + α + k α T t t t t 9 α + σ α αk α αk T α 0 α + σ α αk t + α αk T t +t 4b T α +T α t 4b +4b +T α t T α T t + t t T α t T t + α + σ α + k T t α α αk 4b +T α T α t T t + α + σ α + k 4t T b T t α t + α αk t T t 3 α + σ t t + α αk α + k 4b t t α T α t +T α t t t 4 α + σ t t + α αk t + α + k 4t b T α t t t α +t t t t 5 T t + α + σ t t + α + k T t α α + k t t α t t T α T t 6 T t + α + σ t t + α + k α t + α + k α T t t t t T t +t 4b T α +T α t 4b +4b +T α t T α S T t + t t 3