A Kernel Compression Scheme for Fractional Differential Equations

Abstract: Abstract. The nonlocal nature of the fractional integral makes the numerical treatment of fractional differential equations expensive in terms of computational effort and memory requirements. In this paper we propose a method to reduce these costs while controlling the accuracy of the scheme. This is achieved by splitting the fractional integral of a function f into a local term and a history term. Observing that the history term is a convolution of the history of f and a regular kernel, we derive a multipole … Show more

“…A discontinuous Galerkin time-stepping method has also been proposed for Volterra equations [5,6]. In this paper we propose high-order adaptive methods that are based on an efficient kernel compression [7] approximation of the history term.…”

“…The kernel compression scheme [7] prescribes an approximation to (1.1) given by a linear combination of solutions ψ 1 , . .…”

“…The main result of [7] is the following a priori estimate on J: for T > 0, δ > 0, and an error tolerance ε > 0, the approximation operator I δ,r prescribed by the scheme, given by I δ,r f = S * f , with J = pm, where…”

“…See also [11] for approximation of some functions by sums of exponentials. As the kernel compression scheme is not the main focus of this work, we refer the reader to [7] for a qualitative discussion of the different methods. With relevance to the context of this paper, we mention the following.…”

“…In [12] a fast collocation method is proposed. In addition to the efficient account of the history term, the kernel compression scheme proposed in [7] has other advantages. One is that the theoretical estimates are uniform in α ∈ (0, 1), and f ∈ L 2 (0, T ).…”

High-Order Accurate Adaptive Kernel Compression Time-Stepping Schemes for Fractional Differential Equations

“…A discontinuous Galerkin time-stepping method has also been proposed for Volterra equations [5,6]. In this paper we propose high-order adaptive methods that are based on an efficient kernel compression [7] approximation of the history term.…”

“…The kernel compression scheme [7] prescribes an approximation to (1.1) given by a linear combination of solutions ψ 1 , . .…”

“…The main result of [7] is the following a priori estimate on J: for T > 0, δ > 0, and an error tolerance ε > 0, the approximation operator I δ,r prescribed by the scheme, given by I δ,r f = S * f , with J = pm, where…”

“…See also [11] for approximation of some functions by sums of exponentials. As the kernel compression scheme is not the main focus of this work, we refer the reader to [7] for a qualitative discussion of the different methods. With relevance to the context of this paper, we mention the following.…”

“…In [12] a fast collocation method is proposed. In addition to the efficient account of the history term, the kernel compression scheme proposed in [7] has other advantages. One is that the theoretical estimates are uniform in α ∈ (0, 1), and f ∈ L 2 (0, T ).…”

High-Order Accurate Adaptive Kernel Compression Time-Stepping Schemes for Fractional Differential Equations

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