Markov constant explained

Markov constant of a number
Parity:	even
Domain:	Irrational numbers
Codomain:	Lagrange spectrum with infty
Period:	1
Max:	+infty
Vr1:	\phi
Notes:	This function is undefined on rationals; hence, it is not continuous.

In number theory, specifically in Diophantine approximation theory, the Markov constant

M(\alpha)

of an irrational number

\alpha

is the factor for which Dirichlet's approximation theorem can be improved for

\alpha

History and motivation

Certain numbers can be approximated well by certain rationals; specifically, the convergents of the continued fraction are the best approximations by rational numbers having denominators less than a certain bound. For example, the approximation

\pi ≈	22
	7

is the best rational approximation among rational numbers with denominator up to 56.^[1] Also, some numbers can be approximated more readily than others. Dirichlet proved in 1840 that the least readily approximable numbers are the rational numbers, in the sense that for every irrational number there exists infinitely many rational numbers approximating it to a certain degree of accuracy that only finitely many such rational approximations exist for rational numbers. Specifically, he proved that for any number

\alpha

there are infinitely many pairs of relatively prime numbers

(p,q)

such that

\left|\alpha-

	p
	q

\right|<

	1
	q²

if and only if

\alpha

is irrational.

51 years later, Hurwitz further improved Dirichlet's approximation theorem by a factor of,^[2] improving the right-hand side from

1/q²

1/\sqrt{5}q²

for irrational numbers:

\left|\alpha-

	p
	q

\right|<

	1
	\sqrt{5

q^2}.

The above result is best possible since the golden ratio

\phi

is irrational but if we replace by any larger number in the above expression then we will only be able to find finitely many rational numbers that satisfy the inequality for

\alpha=\phi

Furthermore, he showed that among the irrational numbers, the least readily approximable numbers are those of the form

	a\phi+b
	c\phi+d

where

\phi

is the golden ratio,

a,b,c,d\in\Z

and

ad-bc=\pm1

.^[3] (These numbers are said to be equivalent to

\phi

.) If we omit these numbers, just as we omitted the rational numbers in Dirichlet's theorem, then we can increase the number to 2. Again this new bound is best possible in the new setting, but this time the number , and numbers equivalent to it, limits the bound. If we don't allow those numbers then we can again increase the number on the right hand side of the inequality from 2 to /5, for which the numbers equivalent to

	1+\sqrt{221

} limit the bound. The numbers generated show how well these numbers can be approximated; this can be seen as a property of the real numbers.

However, instead of considering Hurwitz's theorem (and the extensions mentioned above) as a property of the real numbers except certain special numbers, we can consider it as a property of each excluded number. Thus, the theorem can be interpreted as "numbers equivalent to

\phi

, or

	1+\sqrt{221

} are among the least readily approximable irrational numbers." This leads us to consider how accurately each number can be approximated by rationals - specifically, by how much can the factor in Dirichlet's approximation theorem be increased to from 1 for that specific number.

Definition

Mathematically, the Markov constant of irrational

\alpha

is defined as

M(\alpha)=\sup\left\{λ\in\R|\left\vert\alpha-

	p	\right\vert<
	q

	1
	λq²

hasinfinitelymanysolutionsforp,q\in\N\right\}

.^[4] If the set does not have an upper bound we define

M(\alpha)=infty

Alternatively, it can be defined as

\limsup_k\toinfty

2\left\vert

\alpha-	f(k)
	k

\right\vert

where

f(k)

is defined as the closest integer to

\alphak

Properties and results

Hurwitz's theorem implies that

M(\alpha)\ge\sqrt{5}

for all

\alpha\in\R-\Q

\alpha=[a_0;a_1,a_2,...]

is its continued fraction expansion then

M(\alpha)=\limsup_k\toinfty{([a_k+1;a_k+2,a_k+3,...]+[0;a_k,a_k-1,...,a_2,a_1])}

From the above, if

p=\limsup_k\toinfty{a_k}

then

p<M(\alpha)<p+2

. This implies that

M(\alpha)=infty

if and only if

(a_k)

is not bounded. In particular,

M(\alpha)<infty

\alpha

is a quadratic irrationality. In fact, the lower bound for

M(\alpha)

can be strengthened to

M(\alpha)\ge\sqrt{p^2+4}

, the tightest possible.^[5]

The values of

\alpha

for which

M(\alpha)<3

are families of quadratic irrationalities having the same period (but at different offsets), and the values of

M(\alpha)

for these

\alpha

are limited to Lagrange numbers. There are uncountably many numbers for which

M(\alpha)=3

, no two of which have the same ending; for instance, for each number

\alpha=

[\underbrace{1;1,...,1}
	r₁

,2,2,\underbrace{1,1,...,1}
	r₂

,2,2,\underbrace{1,1,...,1}
	r₃

,2,2,...]

where

r_1<r_2<r_{3< …}

M(\alpha)=3

\beta=	p\alpha+q
	r\alpha+s

where

p,q,r,s\in\Z

then

M(\beta)\ge	M(\alpha)
	\left\vertps-rq\right\vert

.^[6] In particular if

\left\vertps-rq\right\vert=1

them

M(\beta)=M(\alpha)

.^[7]

The set

L=\{M(\alpha)|\alpha\in\R-\Q\}

forms the Lagrange spectrum. It contains the interval

[F,infty]

where F is Freiman's constant. Hence, if

m>F ≈ 4.52783

then there exists irrational

\alpha

whose Markov constant is

Numbers having a Markov constant less than 3

Burger et al. (2002)^[8] provides a formula for which the quadratic irrationality

\alpha_n

whose Markov constant is the n^th Lagrange number:

\alpha

2u-3m

	2-4

	n

n+\sqrt{9m

} where

m_n

is the n^th Markov number, and is the smallest positive integer such that

m_n\midu²⁺¹

Nicholls (1978)^[9] provides a geometric proof of this (based on circles tangent to each other), providing a method that these numbers can be systematically found.

Examples

Markov constant of two numbers

Since

	\sqrt{10

}=[1;\overline{1,1,2}],

\begin{align}M\left(

	\sqrt{10

} \right) & = \max([1;\overline{2,1,1}]+[0;\overline{1,2,1}],[1;\overline{1,2,1}]+[0;\overline{2,1,1}],[2;\overline{1,1,2}]+[0;\overline{1,1,2}]) \\ & = \max\left (\frac,\frac,\sqrt \right) \\ & = \sqrt. \end

e=[2;1,2,1,1,4,1,1,6,1,\ldots,1,2n,1,\ldots],M(e)=infty

because the continued fraction representation of is unbounded.

Numbers α_n having Markov constant less than 3

Consider

n=6

; Then

m_n=34

. By trial and error it can be found that

u=13

. Then

\begin{align}\alpha₆&=

2u-3m

	2-4

	6

6+\sqrt{9m

} \\[6pt]& = \frac \\[6pt]&= \frac \\[6pt]&=[0;\overline]. \end

Notes and References

Web site: A063673 (Denominators of sequence of approximations to Pi with increasing denominators, where each approximation is an improvement on its predecessors.) . Fernando. Suren L.. 27 July 2001. The On-Line Encyclopedia of Integer Sequences. 2 December 2019.
Hurwitz. A.. Adolf Hurwitz. 1891. Ueber die angenäherte Darstellung der Irrationalzahlen durch rationale Brüche (On the approximate representation of irrational numbers by rational fractions). Mathematische Annalen. de. 39. 2. 279 - 284. 10.1007/BF01206656. 23.0222.02. 119535189 . contains the actual proof in German.
Web site: Hurwitz's Irrational Number Theorem. Weisstein. Eric W.. 25 November 2019. Wolfram Mathworld. 2 December 2019.
Book: LeVeque, William. Fundamentals of Number Theory. Addison-Wesley Publishing Company, Inc.. 1977. 0-201-04287-8. 251–254.
Hancl. Jaroslav. January 2016. Second basic theorem of Hurwitz. Lithuanian Mathematical Journal. 56. 72–76. 10.1007/s10986-016-9305-4. 124639896 .
1510.02407. Markov constant and quantum instabilities. Journal of Physics A: Mathematical and Theoretical. 49. 15. 155201. 10.1088/1751-8113/49/15/155201. 2016. Pelantová. Edita. Starosta. Štěpán. Znojil. Miloslav. 2016JPhA...49o5201P. 119161523 .
Book: Hazewinkel, Michiel. Encyclopaedia of Mathematics. Springer Science & Business Media. 1990. 9781556080050. 106.
Burger. Edward B.. Folsom. Amanda. Pekker. Alexander. Roengpitya. Rungporn. Snyder. Julia. 2002. On a quantitative refinement of the Lagrange spectrum. Acta Arithmetica. 102. 1. 59–60. 2002AcAri.102...55B. 10.4064/aa102-1-5. free.
Nicholls. Peter. 1978. Diophantine Approximation via the Modular Group. Journal of the London Mathematical Society . Second Series. 17. 11–17. 10.1112/jlms/s2-17.1.11.

Markov constant explained

History and motivation

Definition

Properties and results

Numbers having a Markov constant less than 3

Examples

Markov constant of two numbers

Numbers αn having Markov constant less than 3

See also

Notes and References

Numbers α_n having Markov constant less than 3