A stochastic volatility model for the valuation of temperature derivatives

Aurélien Alfonsi; Nerea Vadillo

doi:10.1093/imaman/dpae013

A stochastic volatility model for the valuation of temperature derivatives

Aurélien Alfonsi
, Nerea Vadillo

Research output: Contribution to journal › Article › peer-review

Abstract

This paper develops a new stochastic volatility model for the average daily temperature. It is a natural extension of a Gaussian model in which the temperature returns to a seasonal trend with a deterministic time-dependent volatility. The new model allows to be more conservative regarding extreme events while keeping tractability. We give a method based on conditional least squares to estimate the parameters on daily data and estimate our model on eight major European cities. We then show how to calculate efficiently the average payoff of weather derivatives both by Monte-Carlo and Fourier transform techniques. This new model allows to better assess the risk related to temperature volatility.

Original language	English
Pages (from-to)	737-785
Number of pages	49
Journal	IMA Journal of Management Mathematics
Volume	35
Issue number	4
DOIs	https://doi.org/10.1093/imaman/dpae013
Publication status	Published - 1 Oct 2024

Keywords

conditional least squares estimation
stochastic volatility model
temperature model
weather derivatives

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10.1093/imaman/dpae013

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abstract = "This paper develops a new stochastic volatility model for the average daily temperature. It is a natural extension of a Gaussian model in which the temperature returns to a seasonal trend with a deterministic time-dependent volatility. The new model allows to be more conservative regarding extreme events while keeping tractability. We give a method based on conditional least squares to estimate the parameters on daily data and estimate our model on eight major European cities. We then show how to calculate efficiently the average payoff of weather derivatives both by Monte-Carlo and Fourier transform techniques. This new model allows to better assess the risk related to temperature volatility.",

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N2 - This paper develops a new stochastic volatility model for the average daily temperature. It is a natural extension of a Gaussian model in which the temperature returns to a seasonal trend with a deterministic time-dependent volatility. The new model allows to be more conservative regarding extreme events while keeping tractability. We give a method based on conditional least squares to estimate the parameters on daily data and estimate our model on eight major European cities. We then show how to calculate efficiently the average payoff of weather derivatives both by Monte-Carlo and Fourier transform techniques. This new model allows to better assess the risk related to temperature volatility.

AB - This paper develops a new stochastic volatility model for the average daily temperature. It is a natural extension of a Gaussian model in which the temperature returns to a seasonal trend with a deterministic time-dependent volatility. The new model allows to be more conservative regarding extreme events while keeping tractability. We give a method based on conditional least squares to estimate the parameters on daily data and estimate our model on eight major European cities. We then show how to calculate efficiently the average payoff of weather derivatives both by Monte-Carlo and Fourier transform techniques. This new model allows to better assess the risk related to temperature volatility.

KW - conditional least squares estimation

KW - stochastic volatility model

KW - temperature model

KW - weather derivatives

U2 - 10.1093/imaman/dpae013

DO - 10.1093/imaman/dpae013

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SP - 737

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JO - IMA Journal of Management Mathematics

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ER -

A stochastic volatility model for the valuation of temperature derivatives

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Keywords

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