The Lp-Lp mapping properties of convolution operators with the affine arclength measure on space curves

Choi, Youngwoo

doi:10.1017/s144678870000375x

Cited by 15 publications

(23 citation statements)

References 9 publications

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“…The theorem generalizes many results previously known for convolution estimates related to space curves, namely [1][2][3][4][5][6]. This article is organized as follows: in the following section, a uniform estimate for convolution operators with measures supported on plane curves.…”

Section: Introductionsupporting

confidence: 61%

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Convolution estimates related to space curves

Choi

2011

J Inequal Appl

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Section: Introductionsupporting

confidence: 61%

“…have been studied by many authors [1][2][3][4][5][6][7][8]. The use of the affine arclength measure was suggested by Drury [2] to mitigate the effect of degeneracy and has been helpful to obtain uniform estimates.…”

Section: Introductionmentioning

confidence: 99%

Convolution estimates related to space curves

Choi

2011

J Inequal Appl

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“…The paper [8] contains a similar result, valid for any real-valued polynomial p. And that estimate is uniform for polynomials of a fixed degree. Theorem 1 below generalizes this: the estimate (1) holds for curves (p 1 (t), p 2 (t)) with dµ = κ 1 3 (s)ds if p 1 and p 2 are real-valued polynomials, and the convolution bounds are uniform in p 1 and p 2 if the degree of these polynomials is fixed.…”

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confidence: 73%

“…The feature, common to these two curves, which in retrospect gives rise to (1) is the fact that on both of them the measure dt is a multiple of the measure κ 1 3 (s)ds where ds is arclength and κ is curvature. Drury [5] was the first to notice the importance of the measures µ given by dµ = κ 1 3 (s)ds in the context of (1). In particular, it was Drury's idea to obtain (1) for the measure dµ = κ 1 3 (s)ds on degenerate curves.…”

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confidence: 99%

Convolution with Measures on Polynomial Curves

Oberlin¹

2002

MATH. SCAND.

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This paper is concerned with convolution estimates for certain measures on degenerate curves in R 2 and R 3 . Analogous estimates in R n , n ≥ 4, were recently obtained for the (nondegenerate) curve (t, t 2 , . . . , t n ) in [4] -see also [9] and [10]. Here is some of the history of this problem. Ideas going back to [6] show, for example, that if µ is the measure given by dt on the circle (cos(t), sin(t)) or on the parabola (t, t 2 ), thenAnd it is easy to see that these estimates are optimal -see [7] for more on this. The feature, common to these two curves, which in retrospect gives rise to (1) is the fact that on both of them the measure dt is a multiple of the measure κ 1 3 (s)ds where ds is arclength and κ is curvature. Drury [5] was the first to notice the importance of the measures µ given by dµ = κ 1 3 (s)ds in the context of (1). In particular, it was Drury's idea to obtain (1) for the measure dµ = κ 1 3 (s)ds on degenerate curves. His result (Theorem 1 in [5]) applies to curves of the form (t, p(t)), so that dµ = |p (t)| 1 3 dt, where the convex function p satisfies certain regularity conditions. The paper [8] contains a similar result, valid for any real-valued polynomial p. And that estimate is uniform for polynomials of a fixed degree. Theorem 1 below generalizes this: the estimate (1) holds for curves (p 1 (t), p 2 (t)) with dµ = κ 1 3 (s)ds if p 1 and p 2 are real-valued polynomials, and the convolution bounds are uniform in p 1 and p 2 if the degree of these polynomials is fixed.Part of the motivation for the above-mentioned work of Drury stems from the fact that convolution estimates for curves in R 2 can be used to obtain convolution estimates for curves in R 3 -see [7]. The main result in [7] is the following: suppose that p 1 (t) and p 2 (t) are polynomials and that the two vectors (p (j ) 1 (t), p (j ) 2 (t)), j = 1, 2, are linearly independent for every t ∈

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“…Drury ([3]) pointed out that the damping factor φ (x) 1/3 could compensate for flatness in such estimates. But his and subsequent results (see, e.g., [1]) gave bounds depending on certain ancillary constants. The (quite simple) proofs of Theorems 1 and 2 have no such dependence.…”

Section: F T φ(T) |mentioning

confidence: 94%