Positive Cubature formulas and Marcinkiewicz-Zygmund inequalities on spherical caps

Abstract

Let Πnd denote the space of all spherical polynomials of degree at most n on the unit sphere of Rd+1, and let d(x, y) denote the usual geodesic distance x· y between x, y∈ . Given a spherical cap B(e,)=\x∈: d(x, e) ≤ \, (e∈, ∈ (0,π) is bounded away from π), we define the metric ρ(x,y):= 1 (d(x, y))2+(-d(x, e)--d(y,e))2, where x, y∈ B(e,). It is shown that given any 1, 1≤ p<∞ and any finite subset of B(e,) satisfying the condition ξ,η∈ ξ≠ η ρ(ξ,η) n with ∈ (0,1], there exists a positive constant C, independent of , n, and , such that, for any f∈Πnd, equation* Σ∈ (x,y∈ Bρ(, /n)|f(x)-f(y)|p) |Bρ(, /n)| (C )p ∫B(e,) |f(x)|p d(x),equation* where d(x) denotes the usual Lebesgue measure on , Bρ(x, r)=\y∈ B(e,): ρ(y,x)≤ r\, (r>0), and |Bρ(x, n)|=∫Bρ(x, /n) d(y) d[ (n)d+1+ ( n)d 1-d(x, e)]. As a consequence, we establish positive cubature formulas and Marcinkiewicz-Zygmund inequalities on the spherical cap B(e,).

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