Liouville's theorem (complex analysis) - Alchetron, the free social encyclopedia

In complex analysis, Liouville's theorem, named after Joseph Liouville, states that every bounded entire function must be constant. That is, every holomorphic function f for which there exists a positive number M such that | f ( z ) | ≤ M for all z in C is constant. Equivalently, non-constant holomorphic functions on C have dense images.

Proof

The theorem follows from the fact that holomorphic functions are analytic. If f is an entire function, it can be represented by its Taylor series about 0:

f ( z ) = ∑ k = 0 ∞ a k z k

where (by Cauchy's integral formula)

a k = f ( k ) ( 0 ) k ! = 1 2 π i ∮ C r f ( ζ ) ζ k + 1 d ζ

and C_r is the circle about 0 of radius r > 0. Suppose f is bounded: i.e. there exists a constant M such that |f(z)| ≤ M for all z. We can estimate directly

| a k | ≤ 1 2 π ∮ C r | f ( ζ ) | | ζ | k + 1 | d ζ | ≤ 1 2 π ∮ C r M r k + 1 | d ζ | = M 2 π r k + 1 ∮ C r | d ζ | = M 2 π r k + 1 2 π r = M r k ,

where in the second inequality we have used the fact that |z|=r on the circle C_r. But the choice of r in the above is an arbitrary positive number. Therefore, letting r tend to infinity (we let r tend to infinity since f is analytic on the entire plane) gives a_k = 0 for all k ≥ 1. Thus f(z) = a₀ and this proves the theorem.

Fundamental theorem of algebra

There is a short proof of the fundamental theorem of algebra based upon Liouville's theorem.

No entire function dominates another entire function

A consequence of the theorem is that "genuinely different" entire functions cannot dominate each other, i.e. if f and g are entire, and |f| ≤ |g| everywhere, then f = α·g for some complex number α. Consider that for g=0 the theorem is trivial so we assume g ≠ 0. Consider the function h = f/g. It is enough to prove that h can be extended to an entire function, in which case the result follows by Liouville's theorem. The holomorphy of h is clear except at points in g⁻¹(0). But since h is bounded and all the zeroes of g are isolated, any singularities must be removable. Thus h can be extended to an entire bounded function which by Liouville's theorem implies it is constant.

If f is less than or equal to a scalar times its input, then it is linear

Suppose that f is entire and |f(z)| is less than or equal to M|z|, for M a positive real number. We can apply Cauchy's integral formula; we have that

| f ′ ( z ) | = 1 2 π | ∮ C r f ( ζ ) ( ζ − z ) 2 d ζ | ≤ 1 2 π ∮ C r | f ( ζ ) | | ( ζ − z ) 2 | | d ζ | ≤ 1 2 π ∮ C r M | ζ | | ( ζ − z ) 2 | | d ζ | = M I 2 π

where I is the value of the remaining integral. This shows that f' is bounded and entire, so it must be constant, by Liouville's theorem. Integrating then shows that f is affine and then, by referring back to the original inequality, we have that the constant term is zero.

Non-constant elliptic functions cannot be defined on C

The theorem can also be used to deduce that the domain of a non-constant elliptic function f cannot be C. Suppose it was. Then, if a and b are two periods of f such that ^a⁄_b is not real, consider the parallelogram P whose vertices are 0, a, b and a + b. Then the image of f is equal to f(P). Since f is continuous and P is compact, f(P) is also compact and, therefore, it is bounded. So, f is constant.

The fact that the domain of a non-constant elliptic function f can not be C is what Liouville actually proved, in 1847, using the theory of elliptic functions. In fact, it was Cauchy who proved Liouville's theorem.

Entire functions have dense images

If f is a non-constant entire function, then its image is dense in C. This might seem to be a much stronger result than Liouville's theorem, but it is actually an easy corollary. If the image of f is not dense, then there is a complex number w and a real number r > 0 such that the open disk centered at w with radius r has no element of the image of f. Define g(z) = 1/(f(z) − w). Then g is a bounded entire function, since

( ∀ z ∈ C ) : | g ( z ) | = 1 | f ( z ) − w | < 1 r ⋅

So, g is constant, and therefore f is constant.

On compact Riemann surfaces

Any holomorphic function on a compact Riemann surface is necessarily constant.

Let f ( z ) be holomorphic on a compact Riemann surface M . By compactness, there is a point p 0 ∈ M where | f ( p ) | attains its maximum. Then we can find a chart from a neighborhood of p 0 to the unit disk D such that f ( ϕ − 1 ( z ) ) is holomorphic on the unit disk and has a maximum at ϕ ( p 0 ) ∈ D , so it is constant, by the maximum modulus principle.

Remarks

Let C ∪ {∞} be the one point compactification of the complex plane C. In place of holomorphic functions defined on regions in C, one can consider regions in C ∪ {∞}. Viewed this way, the only possible singularity for entire functions, defined on C ⊂ C ∪ {∞}, is the point ∞. If an entire function f is bounded in a neighborhood of ∞, then ∞ is a removable singularity of f, i.e. f cannot blow up or behave erratically at ∞. In light of the power series expansion, it is not surprising that Liouville's theorem holds.

Similarly, if an entire function has a pole at ∞, i.e. blows up like zⁿ in some neighborhood of ∞, then f is a polynomial. This extended version of Liouville's theorem can be more precisely stated: if |f(z)| ≤ M.|zⁿ| for |z| sufficiently large, then f is a polynomial of degree at most n. This can be proved as follows. Again take the Taylor series representation of f,

f ( z ) = ∑ k = 0 ∞ a k z k .

The argument used during the proof using Cauchy estimates shows that

( ∀ k ∈ N ) : | a k | ⩽ M r n − k .

So, if k > n,

| a k | ⩽ lim r → + ∞ M r n − k = 0.

Therefore, a_k = 0.

Liouville's theorem does not extend to the generalizations of complex numbers known as double numbers and dual numbers.

References

Liouville's theorem (complex analysis) Wikipedia

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