Dirichlet-multinomial distribution: Difference between revisions

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In [[mathematics]], the '''complex conjugate root theorem''' states that if ''P'' is a [[polynomial]] in one variable with [[Real numbers|real]] [[coefficients]], and ''a''&nbsp;+&nbsp;''bi'' is a [[root of a function|root]] of ''P'' with ''a'' and ''b'' real numbers, then its [[complex conjugate]] ''a''&nbsp;&minus;&nbsp;''bi'' is also a root of ''P''.<ref>{{cite book|title=Maynooth Mathematical Olympiad Manual|author=Anthony G. O'Farell and Gary McGuire|pages=104|chapter=Complex numbers, 8.4.2 Complex roots of real polynomials|year=2002|publisher=Logic Press |isbn=0954426908}} Preview available at [http://books.google.com/books?q=Maynooth+Mathematical+Olympiad+Manual&ots=xQ0hpAQkpc&sa=X&oi=print&ct=title Google books]</ref>
 
It follows from this (and the [[fundamental theorem of algebra]]), that if the degree of a real polynomial is odd, it must have at least one real root.<ref name=Jeffrey>{{cite book|title=Complex Analysis and Applications|author=Alan Jeffrey|chapter=Analytic Functions|pages=22&ndash;23|year=2005|publisher=CRC Press|id=ISBN 158488553X}}</ref>  That fact can also be proven by using the [[intermediate value theorem]].
 
== Examples and consequences ==
* The polynomial ''x''<sup>2</sup>&nbsp;+&nbsp;1&nbsp;=&nbsp;0 has roots ±''i''.
* Any real square [[matrix(mathematics)|matrix]] of odd degree has at least one real [[eigenvalue]]. For example, if the matrix is [[orthogonal matrix| orthogonal]], then 1 or &minus;1 is an eigenvalue.
* The polynomial
::<math> x^3 - 7x^2 + 41x - 87\, </math>
:has roots
::<math> 3,\, 2 + 5i,\, 2 - 5i,</math>
:and thus can be factored as
::<math> (x - 3)(x - 2 - 5i)(x - 2 + 5i).\,</math>
:In computing the product of the last two factors, the imaginary parts cancel, and we get
::<math> (x - 3)(x^2 - 4x + 29).\,</math>
:The non-real factors come in pairs which when multiplied give quadratic polynomials with real coefficients. Since every polynomial with complex coefficients can be factored into 1st-degree factors (that is one way of stating the [[fundamental theorem of algebra]]), it follows that every polynomial with real coefficients can be factored into factors of degree no higher than 2: just 1st-degree and quadratic factors.
 
=== Corollary on odd-degree polynomials ===
It follows from the present theorem and the [[fundamental theorem of algebra]] that if the degree of a real polynomial is odd, it must have at least one real root.<ref name="Jeffrey"/>
 
This can be proved as follows.
*Since non-real complex roots come in conjugate pairs, there are an even number of them;
*But a polynomial of odd degree has an odd number of roots;
*Therefore some of them must be real.
This requires some care in the presence of [[multiple root]]s; but a complex root and its conjugate do have the same [[Multiplicity (mathematics)|multiplicity]] (and this [[lemma (mathematics)|lemma]] is not hard to prove). It can also be worked around by considering only [[irreducible polynomial]]s; any real polynomial of odd degree must have an irreducible factor of odd degree, which (having no multiple roots) must have a real root by the reasoning above.
 
This corollary can also be proved directly by using the [[intermediate value theorem]].
 
== Simple proof ==
One proof of the theorem is as follows:<ref name=Jeffrey />
 
Consider the polynomial
 
: <math>P(z) = a_0 + a_1z + a_2z^2 + \cdots + a_nz^n</math>
 
where all ''a''<sub>''r''</sub> are real. Suppose some complex number ''&zeta;'' is a root of ''P'', that is ''P''(''&zeta;'')&nbsp;=&nbsp;0. It needs to be shown that
: <math>P(\overline{\zeta}) = 0</math>
 
as well.
 
If ''P''(''&zeta;'')&nbsp;=&nbsp;0, then
 
: <math>a_0 + a_1\zeta + a_2\zeta^2 + \cdots + a_n\zeta^n = 0\,</math>
 
which can be put as
 
: <math>\sum_{r=0}^n a_r\zeta^r = 0.</math>
 
Now
: <math>P(\overline{\zeta}) = \sum_{r=0}^n a_r\left(\overline{\zeta}\right)^r</math>
 
and given the [[Complex_conjugation#Properties|properties of complex conjugation]],
 
: <math>\sum_{r=0}^n a_r\left(\overline{\zeta}\right)^r = \sum_{r=0}^n a_r \overline{\zeta^r} = \sum_{r=0}^n \overline{a_r\zeta^r} = \overline {\sum_{r=0}^n a_r\zeta^r}.</math>
 
Since,
: <math>\overline {\sum_{r=0}^n a_r\zeta^r} = \overline{0}</math>
 
it follows that
 
: <math>\sum_{r=0}^n a_r\left(\overline{\zeta}\right)^r = \overline{0} = 0.</math>
 
That is,
 
: <math>P(\overline{\zeta}) = a_0 + a_1\overline{\zeta} + a_2\left(\overline{\zeta}\right)^2 + \cdots + a_n\left(\overline{\zeta}\right)^n = 0.</math>
 
== Notes ==
<div class="references-small"><references /></div>
 
[[Category:Theorems in complex analysis]]
[[Category:Polynomials]]
[[Category:Theorems in algebra]]
[[Category:Articles containing proofs]]

Revision as of 00:21, 16 January 2014

In mathematics, the complex conjugate root theorem states that if P is a polynomial in one variable with real coefficients, and a + bi is a root of P with a and b real numbers, then its complex conjugate a − bi is also a root of P.[1]

It follows from this (and the fundamental theorem of algebra), that if the degree of a real polynomial is odd, it must have at least one real root.[2] That fact can also be proven by using the intermediate value theorem.

Examples and consequences

  • The polynomial x2 + 1 = 0 has roots ±i.
  • Any real square matrix of odd degree has at least one real eigenvalue. For example, if the matrix is orthogonal, then 1 or −1 is an eigenvalue.
  • The polynomial
x37x2+41x87
has roots
3,2+5i,25i,
and thus can be factored as
(x3)(x25i)(x2+5i).
In computing the product of the last two factors, the imaginary parts cancel, and we get
(x3)(x24x+29).
The non-real factors come in pairs which when multiplied give quadratic polynomials with real coefficients. Since every polynomial with complex coefficients can be factored into 1st-degree factors (that is one way of stating the fundamental theorem of algebra), it follows that every polynomial with real coefficients can be factored into factors of degree no higher than 2: just 1st-degree and quadratic factors.

Corollary on odd-degree polynomials

It follows from the present theorem and the fundamental theorem of algebra that if the degree of a real polynomial is odd, it must have at least one real root.[2]

This can be proved as follows.

  • Since non-real complex roots come in conjugate pairs, there are an even number of them;
  • But a polynomial of odd degree has an odd number of roots;
  • Therefore some of them must be real.

This requires some care in the presence of multiple roots; but a complex root and its conjugate do have the same multiplicity (and this lemma is not hard to prove). It can also be worked around by considering only irreducible polynomials; any real polynomial of odd degree must have an irreducible factor of odd degree, which (having no multiple roots) must have a real root by the reasoning above.

This corollary can also be proved directly by using the intermediate value theorem.

Simple proof

One proof of the theorem is as follows:[2]

Consider the polynomial

P(z)=a0+a1z+a2z2++anzn

where all ar are real. Suppose some complex number ζ is a root of P, that is P(ζ) = 0. It needs to be shown that

P(ζ)=0

as well.

If P(ζ) = 0, then

a0+a1ζ+a2ζ2++anζn=0

which can be put as

r=0narζr=0.

Now

P(ζ)=r=0nar(ζ)r

and given the properties of complex conjugation,

r=0nar(ζ)r=r=0narζr=r=0narζr=r=0narζr.

Since,

r=0narζr=0

it follows that

r=0nar(ζ)r=0=0.

That is,

P(ζ)=a0+a1ζ+a2(ζ)2++an(ζ)n=0.

Notes

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  2. 2.0 2.1 2.2 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

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