Difference between revisions of "Rational approximation of famous numbers"

Revision as of 10:43, 26 June 2006

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Introduction

The Dirichlet's theorem shows that, for each irrational number $x\in\mathbb R$ , the inequality $\left|x-\frac pq\right|<\frac 1{q^2}$ has infinitely many solutions. On the other hand, sometimes it is useful to know that $x$ cannot be approximated by rationals too well, or, more precisely, that $x$ is not a Liouvillian number, i.e., that for some power $M<+\infty$ , the inequality $\left|x-\frac pq\right|\ge \frac 1{q^M}$ holds for all sufficiently large denominators $q$ . So, how does one show that a number is not Liouvillian? The answer is given by the following

Main theorem

Suppose that there exist $\beta>\mu>1$ , $Q>1$ and a sequence of rational numbers $\frac {P_n}{Q_n}$ such that for all $n$ , $Q_n\le Q^n$ and $Q^{-\beta n}< \left|x-\frac {P_n}{Q_n}\right|<Q^{-\mu n}$ . Then, for every $M>\frac\beta{\mu-1}$ , the inequality $\left|x-\frac pq\right|<\frac 1{q^M}$ has only finitely many solutions.

The exact formulation of the main theorem in this article is fitted to the Beukers proof of the non-Liouvillian character of $\pi$ but the general spirit of all such theorems is the same: roughly speaking, they tell you that in order to show that $x$ cannot be approximated by rationals too well, one needs to find plenty of good but not too good rational approximations of $x$ .

Proof of the Main Theorem

Choose the least $n$ such that $Q^{(\mu-1) n}\ge 2q$ , i.e., that $Q^n\ge (2q)^{1/(\mu-1)}$ . Note that for such choice of $n$ , we have $Q^n< Q(2q)^{1/(\mu-1)}$ . There are two possible cases:

Case 1: $\frac pq=\frac {P_n}{Q_n}$ . Then $\left|x-\frac pq\right|=\left|x-\frac {P_n}{Q_n}\right|>Q^{-\beta n}>Q^{-\beta}\frac 1{(2q)^{\frac \beta{\mu-1}}}>\frac 1{q^M}$ if $q$ is large enough.

Case 2: $\frac pq\ne \frac {P_n}{Q_n}$ . Then $\left|x-\frac pq\right|\ge \left|\frac pq-\frac{P_n}{Q_n}\right|-\left|x-\frac {P_n}{Q_n}\right| >\frac 1{qQ_n}-Q^{-\mu n}\ge Q^{-n}\left(\frac 1q-\frac 1{Q^{(\mu-1)n}}\right)\ge \frac 1{2qQ^n}\ge Q^{-1}\frac 1{(2q)^{\frac \mu{\mu-1}}}>\frac 1{q^M}$ if $q$ is large enough (recall that $\mu<\beta$ ).

@@ Line 11: / Line 11: @@
 The exact formulation of the main theorem in this article is fitted to the Beukers proof of the non-Liouvillian character of <math>\pi</math> but the general spirit of all such theorems is the same: roughly speaking, they tell you that in order to show that <math>x</math> cannot be approximated by rationals too well, one needs to find plenty of good but not too good rational approximations of <math>x</math>.
 ==Proof of the Main Theorem==
+Choose the least <math>n</math> such that <math>Q^{(\mu-1) n}\ge 2q</math>, i.e., that <math>Q^n\ge (2q)^{1/(\mu-1)}</math>. Note that for such choice of <math>n</math>, we have <math>Q^n< Q(2q)^{1/(\mu-1)}</math>. There are two possible cases:
+'''Case 1:''' <math>\frac pq=\frac {P_n}{Q_n}</math>. Then <math>\left|x-\frac pq\right|=\left|x-\frac {P_n}{Q_n}\right|>Q^{-\beta n}>Q^{-\beta}\frac 1{(2q)^{\frac \beta{\mu-1}}}>\frac 1{q^M}</math> if <math>q</math> is large enough.
+'''Case 2:''' <math>\frac pq\ne \frac {P_n}{Q_n}</math>. Then <math>\left|x-\frac pq\right|\ge
+\left|\frac pq-\frac{P_n}{Q_n}\right|-\left|x-\frac {P_n}{Q_n}\right|
+>\frac 1{qQ_n}-Q^{-\mu n}\ge Q^{-n}\left(\frac 1q-\frac 1{Q^{(\mu-1)n}}\right)\ge \frac 1{2qQ^n}\ge
+Q^{-1}\frac 1{(2q)^{\frac \mu{\mu-1}}}>\frac 1{q^M}</math> if <math>q</math> is large enough (recall that <math>\mu<\beta</math>).

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Difference between revisions of "Rational approximation of famous numbers"

Revision as of 10:43, 26 June 2006

Introduction

Main theorem

Proof of the Main Theorem