A deterministic multiple-shift lattice algorithm for function approximation in Korobov and half-period Cosine spaces

Approximating multivariate periodic functions in weighted Korobov spaces via rank-1 lattices is bottlenecked by frequency aliasing. Existing optimal-rate methods rely on randomized constructions or massive pre-computations. We propose a fully deterministic multiple-shift lattice algorithm without pre pre-computations. First, we develop a uniform shift framework for aliased frequency fibers that decouples and reduces sampling costs. Second, leveraging the Chinese Remainder Theorem and the Weil bound, we introduce an adaptive hybrid construction that algebraically guarantees the full rank and bounded condition number of the reconstruction matrix. We rigorously prove that this deterministic method maintains the optimal convergence rate in the worst-case setting. Furthermore, we extend this framework to non-periodic domains via the tent transformation. By establishing a strict projection equivalence, we prove the algorithm attains optimal $L_2$ and $L_\infty$ approximation orders in the half-period cosine space, successfully resolving an open theoretical problem posed by Suryanarayana et al. (2016). This mathematically validates the proposed algorithm as a generic meshless spectral solver for high-dimensional boundary value problems, such as the Poisson equation with Neumann conditions. Numerical experiments corroborate the theoretical bounds, demonstrating an order-of-magnitude reduction in sampling complexity over probabilistic baselines while ensuring absolute deterministic stability.