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The Generalized Gamma Distribution as a Useful RND under Heston’s Stochastic Volatility Model

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  • Benzion Boukai

    (Department of Mathematical Sciences, Indiana University—Purdue University Indianapolis (IUPUI), Indianapolis, IN 46202, USA)

Abstract

We present the Generalized Gamma (GG) distribution as a possible risk neutral distribution (RND) for modeling European options prices under Heston’s stochastic volatility (SV) model. We demonstrate that under a particular reparametrization, this distribution, which is a member of the scale-parameter family of distributions with the mean being the forward spot price, satisfies Heston’s solution and hence could be used for the direct risk-neutral valuation of the option price under Heston’s SV model. Indeed, this distribution is especially useful in situations in which the spot’s price follows a negatively skewed distribution for which Black–Scholes-based (i.e., the log-normal distribution) modeling is largely inapt. We illustrate the applicability of the GG distribution as an RND by modeling market option data on three large market-index exchange-traded funds (ETF), namely the SPY, IWM and QQQ as well as on the TLT (an ETF that tracks an index of long-term US Treasury bonds). As of the writing of this paper (August 2021), the option chain of each of the three market-index ETFs shows a pronounced skew of their volatility ‘smile’, which indicates a likely distortion in the Black–Scholes modeling of such option data. Reflective of entirely different market expectations, this distortion in the volatility ‘smile’ appears not to exist in the TLT option data. We provide a thorough modeling of the option data we have on each ETF (with the 15 October 2021 expiration) based on the GG distribution and compare it to the option pricing and RND modeling obtained directly from a well-calibrated Heston’s SV model (both theoretically and also empirically, using Monte Carlo simulations of the spot’s price). All three market-index ETFs exhibited negatively skewed distributions, which are well-matched with those derived under the GG distribution as RND. The inadequacy of the Black–Scholes modeling in such instances, which involves negatively skewed distribution, is further illustrated by its impact on the hedging factor, delta, and the immediate implications to the retail trader. Similarly, the closely related Inverse Generalized Gamma distribution (IGG) is also proposed as a possible RND for Heston’s SV model in situations involving positively skewed distribution. In all, utilizing the Generalized Gamma distributions as possible RNDs for direct option valuations under the Heston’s SV is seen as particularly useful to the retail traders who do not have the numerical tools or the know-how to fine-calibrate this SV model.

Suggested Citation

  • Benzion Boukai, 2022. "The Generalized Gamma Distribution as a Useful RND under Heston’s Stochastic Volatility Model," JRFM, MDPI, vol. 15(6), pages 1-18, May.
  • Handle: RePEc:gam:jjrfmx:v:15:y:2022:i:6:p:238-:d:824638
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    References listed on IDEAS

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    1. Ben Boukai, 2020. "How Much Is Your Strangle Worth? On the Relative Value of the Strangle under the Black-Scholes Pricing Model," Applied Economics and Finance, Redfame publishing, vol. 7(4), pages 138-146, July.
    2. Bakshi, Gurdip & Cao, Charles & Chen, Zhiwu, 1997. "Empirical Performance of Alternative Option Pricing Models," Journal of Finance, American Finance Association, vol. 52(5), pages 2003-2049, December.
    3. Fischer Black, 1989. "How To Use The Holes In Black‐Scholes," Journal of Applied Corporate Finance, Morgan Stanley, vol. 1(4), pages 67-73, January.
    4. Cox, John C. & Ross, Stephen A., 1976. "The valuation of options for alternative stochastic processes," Journal of Financial Economics, Elsevier, vol. 3(1-2), pages 145-166.
    5. Black, Fischer & Scholes, Myron S, 1973. "The Pricing of Options and Corporate Liabilities," Journal of Political Economy, University of Chicago Press, vol. 81(3), pages 637-654, May-June.
    6. Ben Boukai, 2020. "How much is your Strangle worth? On the relative value of the $\delta-$Symmetric Strangle under the Black-Scholes model," Papers 2003.03876, arXiv.org, revised May 2020.
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