Nonlinear filtering based on density approximation and deep BSDE prediction
By: Kasper Bågmark, Adam Andersson, Stig Larsson
Potential Business Impact:
Helps computers guess better with new information.
A novel approximate Bayesian filter based on backward stochastic differential equations is introduced. It uses a nonlinear Feynman--Kac representation of the filtering problem and the approximation of an unnormalized filtering density using the well-known deep BSDE method and neural networks. The method is trained offline, which means that it can be applied online with new observations. A mixed a priori-a posteriori error bound is proved under an elliptic condition. The theoretical convergence rate is confirmed in two numerical examples.
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