Steffen Rohde scite author profile

SLE κ is a random growth process based on Loewner's equation with driving parameter a one-dimensional Brownian motion running with speed κ. This process is intimately connected with scaling limits of percolation clusters and with the outer boundary of Brownian motion, and is conjectured to correspond to scaling limits of several other discrete processes in two dimensions.The present paper attempts a first systematic study of SLE. It is proved that for all κ = 8 the SLE trace is a path; for κ ∈ [0, 4] it is a simple path; for κ ∈ (4, 8) it is a self-intersecting path; and for κ > 8 it is space-filling.It is also shown that the Hausdorff dimension of the SLE κ trace is almost surely (a.s.) at most 1 + κ/8 and that the expected number of disks of size ε needed to cover it inside a bounded set is at least ε −(1+κ/8)+o(1) for κ ∈ [0, 8) along some sequence ε 0. Similarly, for κ ≥ 4, the Hausdorff dimension of the outer boundary of the SLE κ hull is a.s. at most 1 + 2/κ, and the expected number of disks of radius ε needed to cover it is at least ε −(1+2/κ)+o(1) for a sequence ε 0.

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Basic properties of SLE

Rohde

Schramm

2011

283

418

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SLEt<; is a random growth process based on Loewner's equation with driving parameter a one-dimensional Brownian motion running with speed K,. This process is intimately connected with scaling limits of percolation clusters and with the outer boundary of Brownian motion, and is conjectured to correspond to scaling limits of several other discrete processes in two dimensions.The present paper attempts a first systematic study of SLE.

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Convergence of a Variant of the Zipper Algorithm for Conformal Mapping

Marshall¹,

Rohde²

2007

SIAM J. Numer. Anal.

101

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In the early 1980s an elementary algorithm for computing conformal maps was discovered by R. Kühnau and the first author. The algorithm is fast and accurate, but convergence was not known. Given points z 0 , . . . , zn in the plane, the algorithm computes an explicit conformal map of the unit disk onto a region bounded by a Jordan curve γ with z 0 , . . . , zn ∈ γ. We prove convergence for Jordan regions in the sense of uniformly close boundaries and give corresponding uniform estimates on the closed region and the closed disc for the mapping functions and their inverses. Improved estimates are obtained if the data points lie on a C 1 curve or a K-quasicircle. The algorithm was discovered as an approximate method for conformal welding; however, it can also be viewed as a discretization of the Loewner differential equation. Introduction.Conformal maps have applications to problems in physics, engineering, and mathematics, but how do you find a conformal map, say, of the upper-half plane H to a complicated region? Rather few maps can be given explicitly by hand, so that a computer must be used to find the map approximately. One reasonable way to describe a region numerically is to give a large number of points on the boundary (see Figure 1). One way to say that a computed map defined on H is "close" to a map to the region is to require that the boundary of the image be uniformly close to the polygonal curve through the data points. Indeed, the only information we may have about the boundary of a region is this collection of data points.In the early 1980s an elementary algorithm was discovered independently by Kühnau [K] and the first author. The algorithm is fast and accurate, but convergence was not known. The purpose of this paper is to prove convergence in the sense of uniformly close boundaries and discuss related numerical issues. In many applications both the conformal map and its inverse are required. One important aspect of the algorithm that sets it apart from others is that this algorithm finds both maps simultaneously.The algorithm can be viewed as an approximate solution to a conformal welding problem or as a discretization of the Loewner differential equation. The approximation to the conformal map is obtained as a composition of conformal maps onto slit half planes. Osculation methods also approximate a conformal map by repeated composition of simple maps. See Henrici [H] for a discussion of osculation methods and uniform convergence on compact sets. The algorithms of the present article follow the boundary of a given region much more closely than, for instance, the Koebe algorithm and give uniform convergence on all of H rather than just on compact subsets. Uniform convergence on the closure of the region is particularly important in applications

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The Loewner differential equation and slit mappings

Marshall

Rohde

2005

J. Amer. Math. Soc.

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Hausdorff Dimension and mean porosity

Koskela

Rohde

1997

Mathematische Annalen

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Steffen Rohde

Basic properties of SLE

Basic properties of SLE

Convergence of a Variant of the Zipper Algorithm for Conformal Mapping

The Loewner differential equation and slit mappings

Hausdorff Dimension and mean porosity

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