Risk Analysis and Hedging of Parisian Options under a Jump‐Diffusion Model

Kim, Kyoung-Kuk; Lim, Dong-Young

doi:10.1002/fut.21757

“…Chung and Shih (2009); Ruas et al (2013) used calendar-spread approaches for American options whereas Chung et al (2013a,b); did for American barriers and for double barriers. Parisian options, which are classified as occupation time derivatives in Broadie and Detemple (2004), are added to the list (Kim and Lim, 2016). More recently, Kim and Lim (2019) proposed a recursive method for autocallable structured products based on the results developed in this paper.…”

Section: Introductionmentioning

confidence: 99%

Integral Equation Based Approach for Static Options Replication

Kim

¹

,

Lim

²

2018

SSRN Journal

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This study provides a systematic and unified approach for constructing exact and static replications for exotic options, using the theory of integral equations. In particular, we focus on barrier-type options including standard, double and sequential barriers. Our primary approach to static options replication is the DEK method proposed by Derman et al. (1995). However, our solution approach is novel in the sense that we study its continuous-time version using integral equations. We prove the existence and uniqueness of hedge weights under certain conditions. Further, if the underlying dynamics is time-homogeneous, then hedge weights can be explicitly found via Laplace transforms. Based on our framework, we propose an improved version of the DEK method. This method is applicable under general Markovian diffusion with killing.

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A general approach for Parisian stopping times under Markov processes

Zhang

¹

,

Li

²

2023

Finance Stoch

5

0

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Static replication of barrier-type options via integral equations

Kim

¹

,

Lim

²

2020

Quantitative Finance

Self Cite

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This study provides a systematic and unified approach for constructing exact and static replications for exotic options, using the theory of integral equations. In particular, we focus on barrier-type options including standard, double and sequential barriers. Our primary approach to static options replication is the DEK method proposed by Derman et al. (1995). However, our solution approach is novel in the sense that we study its continuous-time version using integral equations. We prove the existence and uniqueness of hedge weights under certain conditions. Further, if the underlying dynamics is time-homogeneous, then hedge weights can be explicitly found via Laplace transforms. Based on our framework, we propose an improved version of the DEK method. This method is applicable under general Markovian diffusion with killing.

show abstract

Risk Analysis and Hedging of Parisian Options under a Jump‐Diffusion Model

Cited by 6 publications

References 32 publications

Integral Equation Based Approach for Static Options Replication

Integral Equation Based Approach for Static Options Replication

A general approach for Parisian stopping times under Markov processes

Static replication of barrier-type options via integral equations

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