Number theory/Signed Articles/Elementary diophantine approximations: Difference between revisions

The theory of diophantine approximations is a chapter of number theory, which in turn is a part of mathematics. It studies the approximations of real numbers by rational numbers. This article presents an elementary introduction to diophantine approximations, as well as an introduction to number theory via diophantine approximations.

Introduction

In the everyday life our civilization applies mostly (finite) decimal fractions ${\displaystyle \ {\frac {k}{10^{n}}}.}$  Decimal fractions are used both as certain values, e.g. $5.85, and as approximations of the real numbers, e.g. ${\displaystyle \ \pi \approx 3.14159.}$  However, the field of all rational numbers is much richer than the ring of the decimal fractions (or of the binary fractions ${\displaystyle \ {\frac {k}{2^{n}}},}$  which are used in the computer science). For instance, the famous approximation ${\displaystyle \ \pi \approx {\frac {355}{113}}}$  has denominator 113 much smaller than 10⁵ but it provides a better approximation than the decimal one, which has five digits after the decimal point.

How well can real numbers (all of them or the special ones) be approximated by rational numbers? A typical Diophantine approximation result states:

Theorem  Let ${\displaystyle \ a}$  be an arbitrary real number. Then

• ${\displaystyle \ a}$  is rational   ${\displaystyle \Leftrightarrow }$   there exists a real number C > 0 such that

${\displaystyle \left|a-{\frac {x}{y}}\right|>{\frac {C}{y}}}$

for arbitrary integers ${\displaystyle \ (x,y)}$  such that ${\displaystyle \ y>0}$  and ${\displaystyle \ a\neq {\frac {x}{y}};}$

• (Adolph Hurwitz)   ${\displaystyle \ a}$  is irrational   ${\displaystyle \Leftrightarrow }$   there exist infinitely many pairs of integers ${\displaystyle \ (x,y)}$  such that ${\displaystyle \ y>0}$  and

${\displaystyle \left|a-{\frac {x}{y}}\right|<{\frac {1}{{\sqrt {5}}\cdot y^{2}}}.}$

Remark  Implication   ${\displaystyle \Leftarrow }$   of the first part of the theorem is a simple and satisfaction bringing exercise.

Notation

• ${\displaystyle \Leftarrow :\Rightarrow \ }$   —   "equivalent by definition" (i.e. "if and only if");
• ${\displaystyle :=\ }$   —   "equals by definition";
• ${\displaystyle \exists }$   —   "there exists";
• ${\displaystyle \forall }$   —   "for all";
• ${\displaystyle a\in A\ }$   —   "${\displaystyle a\ }$  is an element of set ${\displaystyle \ A}$";

• ${\displaystyle \mathbb {N} \ :=\ \{1,2\dots \}}$  —  the semiring of the natural numbers;
• ${\displaystyle \mathbb {Z} _{+}\ :=\ \{0,1,\dots \}}$  —  the semiring of the non-negative integers;
• ${\displaystyle \mathbb {Z} \ :=\ \{-2,-1,1,2\dots \}}$  —  the ring of integers;
• ${\displaystyle \mathbb {Q} }$  —  the field of rational numbers;
• ${\displaystyle \mathbb {R} }$  —  the field of real numbers;

• ${\displaystyle (x;y)\ :=\{t\in \mathbb {R} :\,x<t<y\}}$
• ${\displaystyle |(x;y)|\ :=y-x}$
• ${\displaystyle {\mathit {Span}}(x,y)\ :=\ \left(\min \left(x,y\right);\,\max \left(x,y\right)\right)}$

• ${\displaystyle x|y\ }$   —   "${\displaystyle x\ }$  divides ${\displaystyle \ y}$"   (i.e. ${\displaystyle {\frac {y}{x}}\in \mathbb {Z} }$);
• ${\displaystyle \gcd(a,b)\ }$  —  the greatest common divisor of integers ${\displaystyle \ a}$  and ${\displaystyle \ b.}$

The method of neighbors and median

In this section we will quickly obtain some results about approximating irrational numbers by rational. To this end we will not worry about the details of the difference between a rational number and a fraction (with integer numerator and denominator)—this will not cause any problems; fully crisp notions will be developed in the next sections, they will involve 2-dimensional vectors and 2x2 matrices. This section is still introductory. It is supposed to provide quick insight into the topic.

Definitions

Fractions ${\displaystyle {\frac {a}{c}}}$  and ${\displaystyle {\frac {b}{d}},}$  with integer numerators and natural denominators, are called neighbors (in the given order)   ${\displaystyle \Leftarrow :\Rightarrow }$

${\displaystyle {\frac {a}{c}}-{\frac {b}{d}}\ =\ {\frac {1}{c\cdot d}}}$

Fraction ${\displaystyle {\frac {a}{c}}}$  is called the top neighbor of the other, ${\displaystyle {\frac {b}{d}}}$  is called the bottom neighbor, and the interval ${\displaystyle \ {\mathit {Span}}({\frac {a}{c}},{\frac {b}{d}})}$  is called neighborhood; thus a neighborhood is an open interval such that its endpoints are neighbors.

• If  ${\displaystyle {\frac {a}{c}}}$  and ${\displaystyle {\frac {b}{d}}}$  are neighbors then  ${\displaystyle \ a\cdot b\geq 0}$   ( i.e.  ${\displaystyle {\frac {a}{c}}\cdot {\frac {b}{d}}\ \geq 0}$ ).

• Let ${\displaystyle \ a,b,c,d\in \mathbb {N} .}$   Fractions ${\displaystyle {\frac {a}{c}}}$  and ${\displaystyle {\frac {b}{d}}}$  are neighbors   ${\displaystyle \Leftrightarrow }$   fractions ${\displaystyle {\frac {d}{b}}}$  and ${\displaystyle {\frac {c}{a}}}$  are neighbors   ${\displaystyle \Leftrightarrow }$   fractions ${\displaystyle {\frac {-b}{d}}}$  and ${\displaystyle {\frac {-a}{c}}}$  are neighbors.

Examples:

• Fractions ${\displaystyle {\frac {n+1}{1}}}$  and ${\displaystyle {\frac {n}{1}}}$  are neighbors for every positive integer ${\displaystyle \ n.}$

• Fractions ${\displaystyle {\frac {1}{n}}}$  and ${\displaystyle {\frac {1}{n+1}}}$  are neighbors for every positive integer ${\displaystyle \ n.}$

Thus it easily follows that for every positive irrational number ${\displaystyle \ x}$  there exists a pair of neighbors  ${\displaystyle {\frac {a}{c}}}$  and  ${\displaystyle {\frac {b}{d}},}$  with positive numerators and denominators, such that:

${\displaystyle {\frac {a}{c}}\ >\ x\ >\ {\frac {b}{d}}}$ 

Definition  A pair of neighboring fractions ${\displaystyle \left({\frac {a}{c}},{\frac {b}{d}}\right),}$  with integer numerators and natural denominators, is called a top pair   ${\displaystyle \Leftarrow :\Rightarrow \ c>d.}$   Otherwise it is called a bottom pair.

Thus now we have notions of top/bottom neighbors and of top/bottom pairs of neighbors.

• Let  ${\displaystyle \left({\frac {a}{c}},{\frac {b}{d}}\right),}$  be a pair of neighbors. Then  ${\displaystyle \left({\frac {a}{c}},{\frac {a+b}{c+d}}\right)}$  is a top pair of neighbors, and  ${\displaystyle \left({\frac {a+b}{c+d}},{\frac {b}{d}}\right)}$  is a bottom pair of neighbors.

First results

Theorem  Let fractions ${\displaystyle {\frac {a}{c}}}$  and ${\displaystyle {\frac {b}{d}},}$  with integer numerators and natural denominators, be neighbors. Then

• if integers ${\displaystyle \ t>0}$  and ${\displaystyle \ s}$  are such that   ${\displaystyle \ {\frac {a}{c}}>{\frac {s}{t}}>{\frac {b}{d}},}$   then   ${\displaystyle t\geq c+d;}$

• the median  ${\displaystyle {\frac {a+b}{c+d}}}$  is a bottom neighbor of  ${\displaystyle {\frac {a}{c}},}$  and a top neighbor of  ${\displaystyle {\frac {b}{d}};}$ 

• let  ${\displaystyle \ x}$  be an irrational number such that   ${\displaystyle {\frac {a}{c}}\ >\ x\ >\ {\frac {b}{d}};}$   then

${\displaystyle 0\ <\ \max({\frac {a}{c}}-x,\,x-{\frac {b}{d}})\ <\ {\frac {1}{c\cdot d}}}$

and

${\displaystyle 0\ <\ {\frac {a}{c}}-x\ <\ {\frac {1}{2\cdot c^{2}}}}$       or       ${\displaystyle 0\ <\ x-{\frac {b}{d}}\ <\ {\frac {1}{2\cdot d^{2}}}}$

Proof   Let   ${\displaystyle \ {\frac {a}{c}}>{\frac {s}{t}}>{\frac {b}{d}};}$   then

${\displaystyle {\frac {a}{c}}-{\frac {s}{t}}\ \geq \ {\frac {1}{c\cdot t}}}$     and     ${\displaystyle {\frac {s}{t}}-{\frac {b}{d}}\ \geq \ {\frac {1}{d\cdot t}}}$

and

${\displaystyle {\frac {1}{c\cdot t}}+{\frac {1}{d\cdot t}}\ \leq {\frac {1}{c\cdot d}}}$

Multiplying this inequality by  ${\displaystyle c\cdot d\cdot t\ }$ gives

${\displaystyle t\geq c+d}$

which is the first part of our theorem.

The second part of the theorem is obtained by a simple calculation, straight from the definition of the neighbors.

The first inequality of the third part of the theorem is instant:

${\displaystyle \max({\frac {a}{c}}-x,\,x-{\frac {b}{d}})\ <\ ({\frac {a}{c}}-x)+(x-{\frac {b}{d}})\ =\ {\frac {1}{c\cdot d}}}$

Next,

${\displaystyle \left({\frac {1}{c}}-{\frac {1}{d}}\right)^{2}\ \geq \ 0}$

hence

${\displaystyle {\frac {1}{2\cdot c^{2}}}+{\frac {1}{2\cdot d^{2}}}\ \geq \ {\frac {1}{c\cdot d}}\ =\ {\frac {a}{c}}-{\frac {b}{d}}}$

${\displaystyle =\ \left|{\mathit {Span}}({\frac {a}{c}},{\frac {b}{d}})\right|}$

and

${\displaystyle {\frac {b}{d}}+{\frac {1}{2\cdot d^{2}}}\ \geq \ {\frac {a}{c}}-{\frac {1}{2\cdot c^{2}}}}$

i.e.

${\displaystyle {\mathit {Span}}\left({\frac {a}{c}},{\frac {a}{c}}-{\frac {1}{2\cdot c^{2}}}\right)\ \cup \ {\mathit {Span}}\left({\frac {b}{d}}+{\frac {1}{2\cdot d^{2}}},{\frac {b}{d}}\right)\ \backslash \ \mathbb {Q} \ \supseteq \ {\mathit {Span}}\left({\frac {a}{c}},{\frac {b}{d}}\right)\ \backslash \ \mathbb {Q} }$

End of proof

Corollary  Let fractions ${\displaystyle {\frac {a}{c}}}$  and ${\displaystyle {\frac {b}{d}},}$  with integer numerators and natural denominators, be neighbors. Then, if integers ${\displaystyle \ t>0}$  and ${\displaystyle \ s}$  are such that   ${\displaystyle \ {\frac {a}{c}}>{\frac {s}{t}}>{\frac {b}{d}},}$   then either

• ${\displaystyle s=a+b\quad \land \quad t=c+d;}$

or

• ${\displaystyle t\ \geq \ c+d+\min(c,d)\ >\ c+d}$

Hurwitz theorem

Let  ${\displaystyle \ x\in \mathbb {R} }$  be an arbitrary irrational number. Then

${\displaystyle \left|x-{\frac {s}{t}}\right|\ <\ {\frac {1}{{\sqrt {5}}\cdot t^{2}}}}$

for infinitely many different ${\displaystyle \ s,t\in \mathbb {Z} \backslash \{0\}.}$

Lemma 1

Let  ${\displaystyle \ c,d\in \mathbb {N} .}$  Let  ${\displaystyle \ C:=c+d.}$  Then:

${\displaystyle c^{2}-{\sqrt {5}}\!\cdot \!c\!\cdot \!d+d\,^{2}\ >\ 0}$

or

${\displaystyle C\,^{2}-{\sqrt {5}}\cdot \!C\!\cdot \!d+d\,^{2}\ >\ 0}$

Proof of lemma 1  It's easy to show that  ${\displaystyle {\sqrt {2}}\cdot c\neq {\sqrt {3-{\sqrt {5}}}}\cdot d.}$  Thus the square of  ${\displaystyle \ X:={\sqrt {2}}\cdot c-{\sqrt {3-{\sqrt {5}}}}\cdot d}$  is positive. Now,

${\displaystyle {\sqrt {2}}\cdot {\sqrt {3-{\sqrt {5}}}}\ =\ {\sqrt {5}}-1}$

which means that we may write  ${\displaystyle \ X^{2}}$  as follows:

${\displaystyle 2\!\cdot \!c^{2}\ -\ 2\!\cdot \!({\sqrt {5}}-1)\cdot c\!\cdot \!d\ +\ (3-{\sqrt {5}})\!\cdot \!d\,^{2}\ >\ 0}$

i.e.

${\displaystyle (c^{2}-{\sqrt {5}}\cdot c\cdot d+d^{2})\ +\ (C^{2}-{\sqrt {5}}\cdot C\cdot d+d^{2})\ >\ 0}$

and lemma 1 follows.  End of proof

Lemma 2

Let  ${\displaystyle \ a,b\in \mathbb {Z} }$  and  ${\displaystyle \ c,d\in \mathbb {N} .}$  Let  ${\displaystyle \ A:=a+b}$  and  ${\displaystyle \ C:=c+d.}$  Furthermore, let fractions  ${\displaystyle {\frac {a}{c}},{\frac {b}{d}},}$  be neighbors, and let:

${\displaystyle {\frac {A}{C}}\ >\ x\ >\ {\frac {b}{d}}}$

where ${\displaystyle \ x}$  is real. Then one of the following three inequalities holds:

• ${\displaystyle 0\ <\ {\frac {a}{c}}-x\ <\ {\frac {1}{{\sqrt {5}}\cdot c^{2}}}}$

• ${\displaystyle 0\ <\ {\frac {A}{C}}-x\ <\ {\frac {1}{{\sqrt {5}}\cdot C^{2}}}}$

• ${\displaystyle 0\ <\ x-{\frac {b}{d}}\ <\ {\frac {1}{{\sqrt {5}}\cdot d^{2}}}}$

Proof  There are two cases along the inequalities of Lemma 1. Let's assume the first one, which is equivalent to:

${\displaystyle {\frac {1}{{\sqrt {5}}\cdot c^{2}}}+{\frac {1}{{\sqrt {5}}\cdot d\,^{2}}}\ >\ {\frac {1}{c\cdot d}}\ =\ {\frac {a}{c}}-{\frac {b}{d}}\ =\ \left|{\mathit {Span}}\left({\frac {a}{c}},{\frac {b}{d}}\right)\right|}$

Thus

${\displaystyle {\frac {b}{d}}+{\frac {1}{{\sqrt {5}}\cdot d\,^{2}}}\ >\ {\frac {a}{c}}-{\frac {1}{{\sqrt {5}}\cdot c^{2}}}}$

which means that

${\displaystyle {\mathit {Span}}\left({\frac {a}{c}},{\frac {a}{c}}-{\frac {1}{{\sqrt {5}}\cdot c^{2}}}\right)\ \cup \ {\mathit {Span}}\left({\frac {b}{d}}+{\frac {1}{{\sqrt {5}}\cdot d\,^{2}}},{\frac {b}{d}}\right)\ \supseteq \ {\mathit {Span}}\left({\frac {a}{c}},{\frac {b}{d}}\right)}$

${\displaystyle \supseteq \ {\mathit {Span}}\left({\frac {A}{C}},{\frac {b}{d}}\right)}$

Thus lemma 2 is proven when the first inequality of lemma 1 holds. By replacing in the above proof the lower case  ${\displaystyle \ a,c,}$  by the upper case  ${\displaystyle \ A,C,}$  we obtain the proof when the second inequality of lemma 1 holds.

End of proof (of lemma 2)

Lemma 2'

Let  ${\displaystyle \ a,b\in \mathbb {Z} }$  and  ${\displaystyle \ c,d\in \mathbb {N} .}$  Let  ${\displaystyle \ A:=a+b}$  and  ${\displaystyle \ C:=c+d.}$  Furthermore, let fractions  ${\displaystyle {\frac {a}{c}},{\frac {b}{d}},}$  be neighbors, and let:

${\displaystyle {\frac {a}{c}}\ >\ x\ >\ {\frac {A}{C}}}$

where ${\displaystyle \ x}$  is real. Then one of the following three inequalities holds:

• ${\displaystyle 0\ <\ x-{\frac {b}{d}}\ <\ {\frac {1}{{\sqrt {5}}\cdot d\,^{2}}}}$

• ${\displaystyle 0\ <\ x-{\frac {A}{C}}<\ {\frac {1}{{\sqrt {5}}\cdot C^{2}}}}$

• ${\displaystyle 0\ <\ {\frac {a}{c}}\ <\ {\frac {1}{{\sqrt {5}}\cdot x^{2}}}}$

Proof  It's similar to the proof of lemma 2. Or one may apply lemma 2 to  ${\displaystyle \ x':=-x,\ a':=-b,\ b':=-a,}$  and  ${\displaystyle \ c':=d,\ d':=c}$, which would provide us with the respective fraction  ${\displaystyle {\frac {s'}{t'}}.}$  Then the required  ${\displaystyle \ s,t,}$  are given by  ${\displaystyle s:=-s',\ t:=t'.}$

End of proof (of lemma 2')

Proof of Hurwitz theorem

When  ${\displaystyle \ x}$  is irrational, then it is squeezed between infinitely many different pairs of neighbors (see part two of the theorem from the First results section). They provide infinitely many different required fractions  ${\displaystyle {\frac {s}{t}}}$  (see lemma 2 and 2' above; but it is not claimed, nor true, that different pairs of neighbors provide different required fractions).

End of proof

Squeezing irrational numbers between neighbors

Let ${\displaystyle \ x>0}$  be an irrational number, We may always squeeze it between the extremal neighbours:

${\displaystyle {\frac {1}{0}}\ >\ x\ >\ {\frac {0}{1}}}$

But if you don't like infinity (on the left above) then you may do one of the two things:

${\displaystyle x>1\quad \quad \Rightarrow \quad \quad {\frac {n+1}{1}}>x>{\frac {n}{1}}}$

or

${\displaystyle x<1\quad \quad \Rightarrow \quad \quad {\frac {1}{n}}>x>{\frac {1}{n+1}}}$

where in each of these two cases  ${\displaystyle \ n\in \mathbb {N} }$   is a respective unique positive integer.

It was mentioned in the previous section (First results) that if fractions ${\displaystyle {\frac {a}{c}}}$  and ${\displaystyle {\frac {b}{d}},}$  with positive (or non-negative) integer numerators and denominators are neighbors then also the top and the bottom (bot  for short) pair:

• ${\displaystyle {\mathit {top}}\!\left({\frac {a}{c}},{\frac {b}{d}}\right)\ :=\ \left({\frac {a}{c}},{\frac {a+b}{b+d}}\right)}$

and

• ${\displaystyle {\mathit {bot}}\!\left({\frac {a}{c}},{\frac {b}{d}}\right)\ :=\ \left({\frac {a+b}{c+d}},{\frac {b}{d}}\right)}$

are both pairs of neighbors.

Let ${\displaystyle \ A_{0}}$  be a pair of neighbors, and ${\displaystyle \ x\in {\mathit {Span}}(A_{0})}$ be an irrational number. Assume that pairs of neighbors ${\displaystyle \ A_{0},\dots ,A_{n-1}}$  are already defined, and that they squeeze ${\displaystyle \ x,}$ i.e. that ${\displaystyle \ x\in {\mathit {Span}}(A_{k})}$  for each ${\displaystyle \ k=0,\dots ,n-1.}$  Then we define ${\displaystyle \ A_{n}}$  as the one of the two pairs: ${\displaystyle \ {\mathit {top}}(A_{n-1})}$  or  ${\displaystyle \ {\mathit {bot}}(A_{n-1}),}$  which squeezes ${\displaystyle \ x.}$  Thus for every positive irrational number we have obtained an infinite sequence of pairs of neighbors, each squeezing the given irrational number more and more. Thus for arbitrary irrational ${\displaystyle \ x}$  there exist fractions of integers ${\displaystyle \ {\frac {s}{t}},}$  with arbitrarily large denominators, such that

${\displaystyle \left|x-{\frac {s}{t}}\right|\ <\ {\frac {1}{{\sqrt {5}}\cdot t^{2}}}}$

(see section Hurwitz theorem).

If cases top-top and bot-bot happen only finitely many times then starting with an ${\displaystyle \ n}$  we get an infinite alternating top-bot-top-bot-... sequence:

${\displaystyle A_{n+1}={\mathit {top}}(A_{n}),\quad A_{n+2}={\mathit {bot}}(A_{n+2}),\quad A_{n+3}={\mathit {top}}(A_{n+1})\quad \dots }$

Then the new neighbor of the ${\displaystyle \ A_{n+k}}$  pair (i.e. the median of the previous pair ${\displaystyle \ A_{n+k-1}}$)  is equal to

${\displaystyle e_{k}\ :=\ {\frac {F_{k+1}\cdot a+F_{k}\cdot b}{F_{k+1}\cdot c+F_{k}\cdot d}}}$

for every ${\displaystyle \ k=1,2,\dots ,}$  where ${\displaystyle \ F_{t}}$  are the Fibonacci numbers, where