Parameter averaging applied to displaced diffusion.

Quantitative Analysis

Parallel Processing

Numerical Analysis

C++ Multithreading

Python for Excel

Python Utilities

Printable PDF file

I.

II.

Pricing and Hedging.

III.

Explicit techniques.

1.

Black-Scholes formula.

2.

Change of variables for Kolmogorov equation.

3.

Mean reverting equation.

4.

5.

Heston equations.

6.

Displaced Heston equations.

A.

Analytical tractability of displaced Heston equations.

B.

Displaced Heston equations with term structure.

a.

Parameter averaging.

b.

Parameter averaging applied to displaced diffusion.

7.

Stochastic volatility.

8.

Markovian projection.

9.

Hamilton-Jacobi Equations.

IV.

V.

Implementation tools.

VI.

VII.

Implementation tools II.

VIII.

Parameter averaging applied to displaced diffusion.

e apply the result of the previous section ( Parameter averaging ) to the equations ( displaced diffusion with term structure ): MATH We approximate $X_{t}$ with the $Y_{t}$ given by MATH and we are seeking for the best parameter . Using the notation of the previous section MATH The is introduced because of the normalization MATH According to the result ( parameter averaging ) the best parameter comes from the relationships MATH According to the relationships and the $X_{0,t}$ is given by the SDE MATH

Copyright 2007