TY - JOUR
T1 - Grid Peeling and the Affine Curve-Shortening Flow
AU - Eppstein, David
AU - Har-Peled, Sariel
AU - Nivasch, Gabriel
N1 - Publisher Copyright:
© 2018 Taylor & Francis.
PY - 2020/9/1
Y1 - 2020/9/1
N2 - In this article, we study an experimentally-observed connection between two seemingly unrelated processes, one from computational geometry and the other from differential geometry. The first one (which we call grid peeling) is the convex-layer decomposition of subsets (Formula presented.) of the integer grid, previously studied for the particular case G = {1, …, m}2 by Har-Peled and Lidický. The second one is the affine curve-shortening flow (ACSF), first studied by Alvarez et al. and Sapiro and Tannenbaum. We present empirical evidence that, in a certain well-defined sense, grid peeling behaves at the limit like ACSF on convex curves. We offer some theoretical arguments in favor of this conjecture. We also pay closer attention to the simple case where (Formula presented.) is a quarter-infinite grid. This case corresponds to ACSF starting with an infinite L-shaped curve, which when transformed using the ACSF becomes a hyperbola for all times t > 0. We prove that, in the grid peeling of (Formula presented.), (1) the number of grid points removed up to iteration n is Θ(n3/2log n); and (2) the boundary at iteration n is sandwiched between two hyperbolas that are separated from each other by a constant factor.
AB - In this article, we study an experimentally-observed connection between two seemingly unrelated processes, one from computational geometry and the other from differential geometry. The first one (which we call grid peeling) is the convex-layer decomposition of subsets (Formula presented.) of the integer grid, previously studied for the particular case G = {1, …, m}2 by Har-Peled and Lidický. The second one is the affine curve-shortening flow (ACSF), first studied by Alvarez et al. and Sapiro and Tannenbaum. We present empirical evidence that, in a certain well-defined sense, grid peeling behaves at the limit like ACSF on convex curves. We offer some theoretical arguments in favor of this conjecture. We also pay closer attention to the simple case where (Formula presented.) is a quarter-infinite grid. This case corresponds to ACSF starting with an infinite L-shaped curve, which when transformed using the ACSF becomes a hyperbola for all times t > 0. We prove that, in the grid peeling of (Formula presented.), (1) the number of grid points removed up to iteration n is Θ(n3/2log n); and (2) the boundary at iteration n is sandwiched between two hyperbolas that are separated from each other by a constant factor.
KW - 11H06
KW - 11P21
KW - 52A10
KW - 53C44
KW - 68U05
KW - affine curve-shortening flow
KW - convex-layer decomposition
KW - curve-shortening flow
KW - integer grid
KW - onion decomposition
UR - http://www.scopus.com/inward/record.url?scp=85047263679&partnerID=8YFLogxK
U2 - 10.1080/10586458.2018.1466379
DO - 10.1080/10586458.2018.1466379
M3 - ???researchoutput.researchoutputtypes.contributiontojournal.article???
AN - SCOPUS:85047263679
SN - 1058-6458
VL - 29
SP - 306
EP - 316
JO - Experimental Mathematics
JF - Experimental Mathematics
IS - 3
ER -