260 likes | 441 Views
Non-Uniform Adaptive Meshing for One-Asset Problems in Finance. Sammy Huen Supervisor: R. Bruce Simpson Scientific Computation Group University of Waterloo. Presentation Outline. Finance Background (Example) Research Goals Motivating Example Non-Uniform Mesh Generation Adaptive Meshing
E N D
Non-Uniform Adaptive Meshing for One-Asset Problems in Finance Sammy Huen Supervisor: R. Bruce Simpson Scientific Computation Group University of Waterloo
Presentation Outline • Finance Background (Example) • Research Goals • Motivating Example • Non-Uniform Mesh Generation • Adaptive Meshing • Results – Digital Option • Conclusions
Call Option Example Today 1 year from today Maturity (T) Gas: $0.70 Exercise Buy: $0.60 Payoff: $0.10 Contract In 1 year, you have the right but not an obligation to buy gas at 0.60 cents per litre. ? Fair Market Value (V) of Contract Gas: $0.50 Let Expire Buy: $0.50 Strike Price (K)
Call Option Value V(S, t) r = 5% = 20% K = $0.60 * At t < T, V satisfies the Black-Scholes PDE (1973)
Hedging • The issuers of the option can greatly reduce risk (hedging) by creating a portfolio that offsets the exposure to fluctuations in the asset price. • Portfolio composed of the option and a quantity of the asset. • For the Black-Scholes model, a possible hedging strategy is based on holding of the asset. • Delta Hedging
Our Research • The value V(S, t) of the option can be estimated by solving BS PDE numerically. • Solved using a static non-uniform mesh {Si}. • As time increases, V changes. • Mesh unchanged • Goal: We want a mesh generator that generates a mesh that adapts to the shape of V over time to efficiently control the error in V and in the portfolio.
Motivation t = 0.053
Motivation t = 0.43
Motivation t = 1.0
Goal – Dynamic Meshing t = 0.053 N = 35
Goal – Dynamic Meshing t = 0.43 N = 55
Goal – Dynamic Meshing t = 1.0 N = 66
Mesh Generator 1. Derefinement Density Function 2. Refinement 3. Equidistribution
Mesh Density Function w(S) > 0 for a S b S
Mesh (De)Refinement • Mesh size not known • Define a distributing weight tol • Insert and delete mesh points so that interval weight
Mesh Equidistribution • {Si} is an equidistributing mesh for w if • Mesh size fixed at N • Get a non-linear system of equations • Use frozen coefficient iteration to solve
Adaptive Meshing • Assume smooth profiles • Min. the Hm-seminorm* of error in piecewise linear interpolating fn of V • for m = 0, 1 MDF 1 & 2 *G.F. Carey and H.T. Dinh. Grading functions and mesh redistribution. SIAM Journal on Numerical Analysis, 22(5):1028-1040, 1985.
Adaptive Meshing • Taking the portfolio into account MDF 3
Other Issues • When to adapt mesh? • Every time step • Interpolation • Tensioned Spline* • Non-Smooth Profiles • Smooth (non-smooth) solution first • Apply previous methods * A.K. Cline. Scalar- and planar-valued curve fitting using splines under tension. Communications of the ACM, 17(4):218—220, 1974.
Mesh Evolution (cont.) * Designed by Forsyth and Windcliff for this problem
Global Option Price Error t = 0.0007 years t = 1 year * Exact values obtained in Matlab
Global Portfolio Error t = 0.0007 years t = 1 year
Conclusions • Adaptive meshing can be more efficient in controlling error • Option price profile • Portfolio profile • Each strategy worked well for digital call options • Similar results for vanilla and discrete barrier call options
Future Work • Consider different payoff functions • butterfly, straddle, bear spread • Consider early exercise • American style contracts • Consider other exotic options • Asian, Parisian • Consider other density functions