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Mathematics and Financial Economics

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13-02-2019

Mean-reverting additive energy forward curves in a Heath–Jarrow–Morton framework

Authors: Fred Espen Benth, Marco Piccirilli, Tiziano Vargiolu

Published in: Mathematics and Financial Economics | Issue 4/2019

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Abstract

In this paper, we make the traditional modeling approach of energy commodity forwards consistent with no-arbitrage. In fact, traditionally energy prices are modeled as mean-reverting processes under the real-world probability measure \(\mathbb {P}\), which is in apparent contradiction with the fact that they should be martingales under a risk-neutral measure \(\mathbb {Q}\). The key point here is that the two dynamics can coexist, provided a suitable change of measure is defined between \(\mathbb {P}\) and \(\mathbb {Q}\). To this purpose, we design a Heath–Jarrow–Morton framework for an additive, mean-reverting, multicommodity market consisting of forward contracts of any delivery period. Even for relatively simple dynamics, we face the problem of finding a density between \(\mathbb {P}\) and \(\mathbb {Q}\), such that the prices of traded assets like forward contracts are true martingales under \(\mathbb {Q}\) and mean-reverting under \(\mathbb {P}\). Moreover, we are also able to treat the peculiar delivery mechanism of forward contracts in power and gas markets, where the seller of a forward contract commits to deliver, either physically or financially, over a certain period, while in other commodity, or stock, markets, a forward is usually settled on a maturity date. By assuming that forward prices can be represented as affine functions of a universal source of randomness, we can completely characterize the models which prevent arbitrage opportunities by formulating conditions under which the change of measure between \(\mathbb {P}\) and \(\mathbb {Q}\) is well defined. In this respect, we prove two results on the martingale property of stochastic exponentials. The first allows to validate measure changes made of two components: an Esscher-type density and a Girsanov transform with stochastic and unbounded kernel. The second uses a different approach and works for the case of continuous density. We show how this framework provides an explicit way to describe a variety of models by introducing, in particular, a generalized Lucia–Schwartz model and a cross-commodity cointegrated market.

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This assumption can be relaxed to \(\int _{\mathbb {R}^k} (\Vert y\Vert ^2\wedge 1)\,\nu (dy)<\infty \) and we could derive analogous results in this section by defining a non-compensated Lévy process \(\widetilde{J}(t):=\int _0^t \int _{\Vert y\Vert <1} y\,\overline{N}(ds,dy)+\int _0^t \int _{\Vert y\Vert \ge 1} y\,N(ds,dy)\). However, since we want to ease the mathematical discussion and to focus on the modeling intepretation, we assume the stronger condition \(\int _{\mathbb {R}^k} \Vert y\Vert ^2\,\nu (dy)<\infty \), that in particular implies that J (as defined in (1)) is a square-integrable martingale component of the SDEs in (2.2) and (2.3). Let us remark that for some of the results treated in this paper, we will need even stronger assumptions on \(\nu \) (cf. Sect. 3.2), which makes it somehow unprofitable to start here with more general assumptions.

We use the “dot” notation \(A\cdot v\) to emphasize that there is a matrix product.

This property follows from (3.21), by observing that \(0=d(U(t)\cdot U^{-1}(t)) = dU(t)\cdot U^{-1}(t)+U(t)\cdot dU^{-1}(t)=-\Theta (t)\cdot U(t)\cdot U^{-1}(t)+U(t)\cdot \Theta (t)\cdot U^{-1}(t)=-\Theta (t)+U(t)\cdot \Theta (t)\cdot U^{-1}(t)\).

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Title: Mean-reverting additive energy forward curves in a Heath–Jarrow–Morton framework
Authors: Fred Espen Benth
Marco Piccirilli
Tiziano Vargiolu
Publication date: 13-02-2019
Publisher: Springer Berlin Heidelberg
Published in: Mathematics and Financial Economics / Issue 4/2019
Print ISSN: 1862-9679
Electronic ISSN: 1862-9660
DOI: https://doi.org/10.1007/s11579-019-00237-x

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