Rouché's theorem: Difference between revisions
No edit summary Tag: Reverted |
|||
Line 3: | Line 3: | ||
{{Complex analysis sidebar}} |
{{Complex analysis sidebar}} |
||
'''Rouché's theorem''', named after [[Eugène Rouché]], states that for any two [[complex number|complex]]-valued [[function (mathematics)|functions]] {{mvar|f}} and {{math|''g''}} [[Holomorphic function|holomorphic]] inside some region <math>K</math> with closed contour <math>\partial K</math>, if {{math|{{!}}''g''(''z''){{!}} < {{!}}''f''(''z''){{!}}}} on <math>\partial K</math>, then {{math|''f''}} and {{math|''f'' + ''g''}} have the same number of zeros inside <math>K</math>, where each zero is counted as many times as its [[Multiplicity (mathematics)|multiplicity]]. This theorem assumes that the contour <math>\partial K</math> is simple, that is, without self-intersections. Rouché's theorem is an easy consequence of a stronger symmetric Rouché's theorem described below. |
'''Rouché's theorem''', named after [[Eugène Rouché]], states that for any two [[complex number|complex]]-valued [[function (mathematics)|functions]] {{mvar|f}} and {{math|''g''}} [[Holomorphic function|holomorphic]] inside some region <math>K</math> with closed contour <math>\partial K</math>, if {{math|{{!}}''g''(''z''){{!}} < {{!}}''f''(''z''){{!}}}} on <math>\partial K</math>, then {{math|''f''}} and {{math|''f'' + ''g''}} have the same number of zeros inside <math>K</math>, where each zero is counted as many times as its [[Multiplicity (mathematics)|multiplicity]]. This theorem assumes that the contour <math>\partial K</math> is simple, that is, without self-intersections. Rouché's theorem is an easy consequence of a stronger symmetric Rouché's theorem described below. |
||
Now me personally, I definitely do not want any polish. |
|||
== Usage == |
== Usage == |
Revision as of 19:32, 4 December 2024
Mathematical analysis → Complex analysis |
Complex analysis |
---|
Complex numbers |
Complex functions |
Basic theory |
Geometric function theory |
People |
Rouché's theorem, named after Eugène Rouché, states that for any two complex-valued functions f and g holomorphic inside some region with closed contour , if |g(z)| < |f(z)| on , then f and f + g have the same number of zeros inside , where each zero is counted as many times as its multiplicity. This theorem assumes that the contour is simple, that is, without self-intersections. Rouché's theorem is an easy consequence of a stronger symmetric Rouché's theorem described below.
Now me personally, I definitely do not want any polish.
Usage
The theorem is usually used to simplify the problem of locating zeros, as follows. Given an analytic function, we write it as the sum of two parts, one of which is simpler and grows faster than (thus dominates) the other part. We can then locate the zeros by looking at only the dominating part. For example, the polynomial has exactly 5 zeros in the disk since for every , and , the dominating part, has five zeros in the disk.
Geometric explanation
It is possible to provide an informal explanation of Rouché's theorem.
Let C be a closed, simple curve (i.e., not self-intersecting). Let h(z) = f(z) + g(z). If f and g are both holomorphic on the interior of C, then h must also be holomorphic on the interior of C. Then, with the conditions imposed above, the Rouche's theorem in its original (and not symmetric) form says that
Notice that the condition |f(z)| > |h(z) − f(z)| means that for any z, the distance from f(z) to the origin is larger than the length of h(z) − f(z), which in the following picture means that for each point on the blue curve, the segment joining it to the origin is larger than the green segment associated with it. Informally we can say that the blue curve f(z) is always closer to the red curve h(z) than it is to the origin.
The previous paragraph shows that h(z) must wind around the origin exactly as many times as f(z). The index of both curves around zero is therefore the same, so by the argument principle, f(z) and h(z) must have the same number of zeros inside C.
One popular, informal way to summarize this argument is as follows: If a person were to walk a dog on a leash around and around a tree, such that the distance between the person and the tree is always greater than the length of the leash, then the person and the dog go around the tree the same number of times.
Applications
Bounding roots
Consider the polynomial with . By the quadratic formula it has two zeros at . Rouché's theorem can be used to obtain some hint about their positions. Since
Rouché's theorem says that the polynomial has exactly one zero inside the disk . Since is clearly outside the disk, we conclude that the zero is .
In general, a polynomial . If for some , then by Rouche's theorem, the polynomial has exactly roots inside .
This sort of argument can be useful in locating residues when one applies Cauchy's residue theorem.
Fundamental theorem of algebra
Rouché's theorem can also be used to give a short proof of the fundamental theorem of algebra. Let and choose so large that: Since has zeros inside the disk (because ), it follows from Rouché's theorem that also has the same number of zeros inside the disk.
One advantage of this proof over the others is that it shows not only that a polynomial must have a zero but the number of its zeros is equal to its degree (counting, as usual, multiplicity).
Another use of Rouché's theorem is to prove the open mapping theorem for analytic functions. We refer to the article for the proof.
Symmetric version
A stronger version of Rouché's theorem was published by Theodor Estermann in 1962.[1] It states: let be a bounded region with continuous boundary . Two holomorphic functions have the same number of roots (counting multiplicity) in , if the strict inequality holds on the boundary
The original version of Rouché's theorem then follows from this symmetric version applied to the functions together with the trivial inequality (in fact this inequality is strict since for some would imply ).
The statement can be understood intuitively as follows. By considering in place of , the condition can be rewritten as for . Since always holds by the triangle inequality, this is equivalent to saying that on , which in turn means that for the functions and are non-vanishing and .
Intuitively, if the values of and never pass through the origin and never point in the same direction as circles along , then and must wind around the origin the same number of times.
Proof of the symmetric form of Rouché's theorem
Let be a simple closed curve whose image is the boundary . The hypothesis implies that f has no roots on , hence by the argument principle, the number Nf(K) of zeros of f in K is i.e., the winding number of the closed curve around the origin; similarly for g. The hypothesis ensures that g(z) is not a negative real multiple of f(z) for any z = C(x), thus 0 does not lie on the line segment joining f(C(x)) to g(C(x)), and is a homotopy between the curves and avoiding the origin. The winding number is homotopy-invariant: the function is continuous and integer-valued, hence constant. This shows
See also
- Fundamental theorem of algebra – Every polynomial has a real or complex root
- Hurwitz's theorem (complex analysis) – Limit of roots of sequence of functions
- Rational root theorem – Relationship between the rational roots of a polynomial and its extreme coefficients
- Properties of polynomial roots – Geometry of the location of polynomial roots
- Riemann mapping theorem – Mathematical theorem
- Sturm's theorem – Counting polynomial roots in an interval
References
This article includes a list of references, related reading, or external links, but its sources remain unclear because it lacks inline citations. (May 2015) |
- ^ Estermann, T. (1962). Complex Numbers and Functions. Athlone Press, Univ. of London. p. 156.
- Beardon, Alan (1979). Complex Analysis: The Argument Principle in Analysis and Topology. John Wiley and Sons. p. 131. ISBN 0-471-99672-6.
- Conway, John B. (1978). Functions of One Complex Variable I. Springer-Verlag New York. ISBN 978-0-387-90328-6.
- Titchmarsh, E. C. (1939). The Theory of Functions (2nd ed.). Oxford University Press. pp. 117–119, 198–203. ISBN 0-19-853349-7.
- Rouché É., Mémoire sur la série de Lagrange, Journal de l'École Polytechnique, tome 22, 1862, p. 193-224. Theorem appears at p. 217. See Gallica archives.