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Valuation of swing options with supplier flexibility – switching and recall features: a methodology note. (English) Zbl 1178.91203

Costantino, M. (ed.) et al., Computational finance and its applications III (Computional Finance 2008), Cádiz, Spain, May 27–29, 2008. Southampton: WIT Press (ISBN 978-1-84564-111-5/hbk). WIT Transactions on Information and communication Technologies 41, 63-70 (2008).
Summary: This paper presents a method for valuation and risk/sensitivity analysis of swing contracts with switching and/or recall features. Standard swing options allow natural gas customers to exercise a limited number of call features over a period (month) to select the optimal amount of energy to receive each period (day) at a given strike price. More complex versions of these instruments also allow the supplier some flexibility. Two supplier-friendly features are discussed in this paper: (1) Switching features: the supplier must fulfill the buyer’s nomination in full, but has a choice of which commodity/delivery location to supply (2) Recall features: the supplier may recall some of the buyer’s nomination amount. This paper offers an algorithm for backward solution. The method draws from P. Jaillet, E. Ronn and S. Tompaidis [“Valuation of commodity based swing options”, Manage. Sci. 50, No. 7, 909–921 (2004)] by using a forest of trees to represent remaining swing rights, but extends it to a two player (customer and supplier) setting. At each stage the players gather the relevant nodes to which they can transition and engage in a Stackelberg game to determine the optimal action. At each point, the game’s outcome is determined employing the game theoretic concept of subgame perfect Nash equilibrium. Because different locations for gas delivery are essentially separate but related markets, the underlying prices to be constructed are two gas locations with a specified correlation. This paper employs M. Rubenstein’s [“Somewhere over the rainbow”, RISK 4 (November 1991), 63–66 (1991); “Return to Oz”, RISK 7 (November 1994), 67–71 (1994)] pyramid methodology for modelling correlated asset price processes. In addition, we adapt the J. C. Hull and A. White [“Numerical procedures for implementing models I: Single factor models”, J. Derivatives 2, 37–48 (1994)] procedure for incorporating drift so that our price pyramid captures the mean reversion feature of natural gas. Finally we make adjustments so that the simulation captures seasonality of natural gas prices.
For the entire collection see [Zbl 1149.91005].

MSC:

91G20 Derivative securities (option pricing, hedging, etc.)
91B25 Asset pricing models (MSC2010)
91G60 Numerical methods (including Monte Carlo methods)
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