Worst-case Lp-approximation of periodic functions using median lattice algorithms

Abstract

We study the worst-case approximation of multivariate periodic functions from the weighted Korobov space Hd,α,γ with smoothness α>1/2 in the Lebesgue norm Lp([0,1]d) for 1 p∞. We analyze a median lattice algorithm that reconstructs a truncated Fourier series by approximating the coefficients on a hyperbolic-cross-type index set using R rank-1 lattice sampling rules with independent randomly chosen generating vectors, and then aggregating the resulting coefficient estimators via the componentwise median. For an odd number of repetitions R>1 and an odd prime lattice size N, we prove high-probability error bounds in both L∞ and L2. Interpolation then yields the result for all 1 p∞. In particular, with a high probability, the algorithm satisfies \[ err(Hd,α,γ,Lp,A)\ \ Cd,α,β,γ,p\, N- α + (12 - 1p)+ + β , 1 p∞,\ β>0, \] where (x)+ = \x, 0\, N is the number of function evaluations, and the weights γ and the constant Cd,α,β,γ,p are independent of N. For p=∞, Cd,α,β,γ,∞ is dimension-independent under the summability condition Σj=1∞ γj1/(2α)<∞. These results extend recent analyses of median-based lattice approximation in L2 and complement related multiple-shift lattice approaches, showing that median aggregation yields nearly optimal Lp-approximation rates (up to logarithmic factors and an arbitrarily small loss) in weighted Korobov spaces.

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…