1. MMC
  2. All Volumes and Issues
  3. Volume 8, Number 1, 2021
  4. The path integral method in interest rate models

The path integral method in interest rate models

MMC.
2021;
Volume 8, Number 1
: pp. 125–136
https://doi.org/10.23939/mmc2021.01.125
Received: September 29, 2020
Accepted: January 28, 2021

Mathematical Modeling and Computing, Vol. 8, No. 1, pp. 125–136 (2021)

Authors:
  1. V. S. Yanishevskyi
  2. L. S. Nodzhak
1
Lviv Polytechnic National University
2
Lviv Polytechnic National University

An application of path integral method to Merton and Vasicek stochastic models of interest rate is considered.  Two approaches to a path integral construction are shown.  The first approach consists in using Wieners measure with the following substitution of solutions of stochastic equations into the models.  The second approach is realised by using transformation from Wieners measure to the integral measure related to the stochastic variables of Merton and Vasicek equations.  The introduction of boundary conditions is considered in the second approach in order to remove incorrect time asymptotes from the classic Merton and Vasicek models of interest rates.  By the example of Merton model with zero drift, a Dirichlet boundary condition is considered.  A path integral representation of term structure of interest rate is obtained.  The estimate of the obtained path integrals is performed, where it is shown that the time asymptote is limited.

interest rate model
stochastic model
transition probability
path integral
  1. Yuh-Dauh Lyuu.  Financial Engineering and Computation: Principles, Mathematics, and Algorithms.  Cambridge University Press (2004).
  2. Privault N.  An elementary introduction to stochastic interest rate modeling.  World Scientific Publishing Co. Pte. Ltd. (2012).
  3. Georges P.  The Vasicek and CIR models and the expectation hypothesis of the interest rate term structure.  Working Paper, Department of Finance (2003).
  4. Decaps M., De Scheppe A., Goovaerts M.  Applications of delta–function perturbation to the pricing of derivative securities.  Physica A. 342, 93–40, 677–692 (2004).
  5. Yanishevsky V. S.  Stochastic methods in modeling of financial processes.  Economics and society.  15, 959–965  (2018), (in Ukrainian).
  6. Yanishevsky V. S.  Option price for Bachelier model with constraints.  Market Infrastructure. 19, 593–598 (2018), (in Ukrainian).
  7. Kleinert H.  Path integrals in quantum mechanics, statistics, polymer physics and financial markets.  World Scientific Publishing Co., Inc., River Edge (2004).
  8. Chaichian M., Demichev A.  Path integrals in physics. Stochastic processes and quantum mechanics.  Taylor & Francis (2001).
  9. Chaichian M., Demichev A.  Path integrals in physics. QFT, statistical physics and modern applications.  Taylor & Francis  (2001).
  10. Baaquie B. E.  Quantum finance. Path Integrals and Hamiltonians for Options and Interest Rates.  Cambridge University Press, New York (2004).
  11. Linetsky V.  The Path Integral Approach to Financial Modeling and Options Pricing.  Computational Economics. 11, 129–163 (1998).
  12. Blazhyevskyi L. F., Yanishevsky V. S.  The path integral representation kernel of evolution operator in Merton–Garman model.  Condensed Matter Physics. 14 (2), 23001 (2011).
  13. Goovaertsa M., De Schepper A., Decampsa M.  Closed-form approximations for diffusion densities: a path integral approach.  Journal of Computational and Applied Mathematics. 164165, 337–364 (2004).
  14. Gardiner C. W.  Handbook of Stochastic Methods: for Physics, Chemistry and the Natural Sciences.  Springer (2004).
  15. Grosche C. δ-function perturbations and boundary problems by path integration.  Annalen der Physik. 2 (6), 557–589 (1993).
  16. Grosche C., Steiner F.  Handbook of Feynman Path Integrals.  Springer, Berlin, Heidelberg (1998).