Regularization by regular noise: a numerical result
Abstract
We study a singular stochastic equation driven by a regular noise of fractional Brownian type with Hurst index H ∈ (1,∞) and drift coefficient b ∈ Cα, where α > 1 - 12H. The strong well-posedness of this equation was first established in [Ger23], a phenomenon referred to as regularization by regular noise. In this note, we provide a corresponding numerical analysis. Specifically, we show that the Euler-Maruyama approximation Xn converges strongly to the unique solution X with rate n-1. Furthermore, under the additional assumption b ∈ C1, we show that n(X - Xn) converges to a non-trivial limit as n ∞, thereby confirming that the rate n-1 is in fact optimal upper bound for this scheme.
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