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A Metaheuristic Approach to Optimize European Call Function with Boundary Conditions

  • Najeeb Alam Khan EMAIL logo , Oyoon Abdul Razzaq and Tooba Hameed
Published/Copyright: June 29, 2018
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Journal of Systems Science and Information
From the journal Journal of Systems Science and Information Volume 6 Issue 3

Abstract

The purpose of this paper is to investigate the pricing European call option valuation problems under the exercise price, maturity, risk-free interest rate, and the volatility function. An advance methodology, Chebyshev simulated annealing neural network (ChSANN), is enforced for the Black-Scholes (B-S) model with boundary conditions. Our scheme is stable and easy to implement on B-S equation, for arbitrary volatility and arbitrary interest rate values. Also, the comparative results demonstrate that the attained approximate solutions are converging towards the exact solution. The graphical results show that the increasing flow of the European call option as the exponential increase takes place in assets. The presented algorithm can be further applied to other financial models with certain boundary conditions. The algorithm of the method shows that the approach can also be easily employed on time-fractional B-S equation.

Keywords: neural network; numerical approximation; Chebyshev polynomials

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Received: 2017-05-31
Accepted: 2017-12-07
Published Online: 2018-06-29

© 2018 Walter De Gruyter GmbH, Berlin/Boston

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https://doi.org/10.21078/JSSI-2018-260-09
Keywords for this article
neural network; numerical approximation; Chebyshev polynomials

Articles in the same Issue

  2. Electricity Price of Hybrid Power System and Decision Making of Renewable Energy Investment Capacity
  4. Modeling Analysis of Complex Products Resource Integration Behavior Under Distributed Collaborative Technology Innovation Mode
  6. The Effect of Transportation and Housing Subsidies on Urban Sprawl
  8. Centralized Decisions for a Two-Stage Supply Chain with Price-Discount Dependent Demand
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  12. Headings of UCAV Based on Nash Equilibrium
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