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Complex Algebra 8 - Exercises - Mathematics, Exercises of Mathematics

Columbia University in the City of New YorkMathematics

In Ahlfors’ first exercise for V.1.3 (p.183) he gives a geometric description of the harmonic function PU(z) on the open unit disc  obtained from Poisson’s integral formula when U is the characteristic function of an arc on the unit circle. Explain this result using a suitable conformal map from  to an infinite strip.

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Math 213a: Complex analysis
Problem Set #7 (5 November 2003):
Harmonic functions and the Dirichlet problem
1. In Ahlfors’ first exercise for V.1.3 (p.183) he gives a geometric description
of the harmonic function PU(z) on the open unit disc obtained from
Poisson’s integral formula when Uis the characteristic function of an arc
on the unit circle. Explain this result using a suitable conformal map
from to an infinite strip.
Some more problems from Ahlfors (V.1.4, p.184; V.2.1, p.196)
2. If Eis a compact subset of a region Ω, prove that there exists a constant M,
depending only on Eand Ω, such that every positive harmonic function
u: (0,) satisfies the inequality u(z0)Mu(z) for all z , z0E.
3. Show that the functions |x|=|Re(z)|,|z|α(all α0), and log(1 + |z|2) are
subharmonic.
4. If vis a C2function on some region, prove that vis subharmonic if and only
if v0. [See Ahlfors for a hint.]
5. Extend Harnack’s principle [Ahlfors V.1.4, Thm.6, 183–4] to subharmonic
functions. (Warning: the conclusion must be weaker, as evidenced by
such counterexamples as n=Ω=C,un=n|z|.)
The final two problems concern a discrete analogue of the Laplacian. We work
on the cubic lattice L=ZnRn, regarded as an infinite graph of degree 2n
(so z, z0Lare adjacent iff |z0z|= 1). An “interior point” of a subset SL
is a point all of whose neighbors are in S; these points constitute the “interior”
of S, whose complement in Sis the “boundary” ∂S of S. A function u:SR
is harmonic if its value at each interior point zSis the average of its values
at the neighbors of z, and subharmonic if u(z)(2n)1P|z0z|=1 u(z0) for all
interior zS. We similarly define (sub)harmonic functions on cL for any c > 0.
6. Suppose Sis finite. Prove that any function U:∂S Rextends to a unique
harmonic function u:SR, which is nonnegative if Uis.
7.Suppose KRnis a convex compact set and vis a harmonic function on
some neighborhood of K. For c > 0 let Sc=cL K, and let ucbe the
harmonic function on Scsuch that uc(z) = v(z) for all z∂Sc(this is well-
defined, by the previous problem). Prove that there exists a constant A,
depending only on Kand u, such that |uc(z)v(z)| Ac2for all zSc.
You may assume the theorem that vis automatically real-analytic; we
didn’t prove this in class for n3, but it follows easily from the Poisson
integral representation of a harmonic function on a closed sphere in Rn.
[This is the beginning of one approach to justifying the numerical approximation
of solutions of the Dirichlet problem on Rnby discrete harmonic functions.]
This problem set is due Wednesday, November 12, at the beginning of class.

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Math 213a: Complex analysis Problem Set #7 (5 November 2003): Harmonic functions and the Dirichlet problem

  1. In Ahlfors’ first exercise for V.1.3 (p.183) he gives a geometric description of the harmonic function PU (z) on the open unit disc ∆ obtained from Poisson’s integral formula when U is the characteristic function of an arc on the unit circle. Explain this result using a suitable conformal map from ∆ to an infinite strip.

Some more problems from Ahlfors (V.1.4, p.184; V.2.1, p.196)

  1. If E is a compact subset of a region Ω, prove that there exists a constant M , depending only on E and Ω, such that every positive harmonic function u : Ω → (0, ∞) satisfies the inequality u(z′) ≤ M u(z) for all z, z′^ ∈ E.
  2. Show that the functions |x| = | Re(z)|, |z|α^ (all α ≥ 0), and log(1 + |z|^2 ) are subharmonic.
  3. If v is a C^2 function on some region, prove that v is subharmonic if and only if ∆v ≥ 0. [See Ahlfors for a hint.]
  4. Extend Harnack’s principle [Ahlfors V.1.4, Thm.6, 183–4] to subharmonic functions. (Warning: the conclusion must be weaker, as evidenced by such counterexamples as Ωn = Ω = C, un = n|z|.)

The final two problems concern a discrete analogue of the Laplacian. We work on the cubic lattice L = Zn^ ∈ Rn, regarded as an infinite graph of degree 2n (so z, z′^ ∈ L are adjacent iff |z′^ − z| = 1). An “interior point” of a subset S ∈ L is a point all of whose neighbors are in S; these points constitute the “interior” of S, whose complement in S is the “boundary” ∂S of S. A function u : S → R is harmonic if its value at each interior point z ∈ S is the average of its values at the neighbors of z, and subharmonic if u(z) ≤ (2n)−^1

|z′−z|=1 u(z ′) for all

interior z ∈ S. We similarly define (sub)harmonic functions on cL for any c > 0.

  1. Suppose S is finite. Prove that any function U : ∂S → R extends to a unique harmonic function u : S → R, which is nonnegative if U is.

7.∗^ Suppose K ∈ Rn^ is a convex compact set and v is a harmonic function on some neighborhood of K. For c > 0 let Sc = cL ∩ K, and let uc be the harmonic function on Sc such that uc(z) = v(z) for all z ∈ ∂Sc (this is well- defined, by the previous problem). Prove that there exists a constant A, depending only on K and u, such that |uc(z) − v(z)| ≤ Ac^2 for all z ∈ Sc. You may assume the theorem that v is automatically real-analytic; we didn’t prove this in class for n ≥ 3, but it follows easily from the Poisson integral representation of a harmonic function on a closed sphere in Rn.

[This is the beginning of one approach to justifying the numerical approximation of solutions of the Dirichlet problem on Rn^ by discrete harmonic functions.]

This problem set is due Wednesday, November 12, at the beginning of class.