Lochs's theorem

Last updated January 15, 2024

In number theory, Lochs's theorem concerns the rate of convergence of the continued fraction expansion of a typical real number. A proof of the theorem was published in 1964 by Gustav Lochs.^[1]

As this limit is only slightly smaller than 1, this can be interpreted as saying that each additional term in the continued fraction representation of a "typical" real number increases the accuracy of the representation by approximately one decimal place. The decimal system is the last positional system for which each digit carries less information than one continued fraction quotient; going to base-11 (changing $\ln(10)$ to $\ln(11)$ in the equation) makes the above value exceed 1.

The reciprocal of this limit,

{\frac {\pi ^{2}}{6\ln(2)\ln(10)}}\approx 1.03064083

(sequence A062542 in the OEIS ),

is twice the base-10 logarithm of Lévy's constant.

A prominent example of a number not exhibiting this behavior is the golden ratio—sometimes known as the "most irrational" number—whose continued fraction terms are all ones, the smallest possible in canonical form. On average it requires approximately 2.39 continued fraction terms per decimal digit.^[3]

Proof

The proof assumes basic properties of continued fractions. Let $T:x\mapsto 1/x\mod 1$ be the Gauss map.

Let $\rho (t)={\frac {1}{(1+t)\ln 2}}$ be the probability density function for the Gauss distribution, which is preserved under the Gauss map.

Since the probability density function is bounded above and below, a set is negligible with respect to the Lebesgue measure iff to the Gauss distribution.

Lemma

Lemma. ${\textstyle {\frac {1}{n}}\ln T^{n}x\to 0}$ .

Proof. Since ${\textstyle T^{n}x\leq 1}$ , we have ${\textstyle {\frac {1}{n}}\ln T^{n}x\to 0}$ iff

\liminf {\frac {1}{n}}\ln T^{n}x=0

Let us consider the set of all ${\textstyle x}$ that have ${\textstyle \liminf {\frac {1}{n}}\ln T^{n}x<0}$ . That is,

\{x:\exists c>0,\forall N\geq 1,\exists n\geq N,T^{n}x<e^{-cn}\}

=\cup _{c>0}\cap _{N\geq 1}\cup _{n\geq N}[0;\mathbb {N} ,\dots ,\mathbb {N} ,a_{n}>e^{cn},\mathbb {N} ,\dots ]

where $[0;\mathbb {N} ,\dots ,\mathbb {N} ,a_{n}>e^{cn},\mathbb {N} ,\dots ]$ denotes the set of numbers whose continued fraction expansion has $a_{n}>e^{cn}$ , but no other constraints. Now, since the Gauss map preserves the Gauss measure,

[0;\mathbb {N} ,\dots ,\mathbb {N} ,a_{n}>e^{cn},\mathbb {N} ,\dots ]

has the same Gauss measure as ${\textstyle [0;a_{n}>e^{cn},\mathbb {N} ,\dots ]}$ , which is the same as

\int _{0}^{e^{-cn}}\rho (t)dt=\log _{2}(1+e^{-cn})\sim {\frac {e^{-cn}}{\ln 2}}

The union over ${\textstyle \cup _{n\geq N}}$ sums to ${\textstyle \sim {\frac {e^{-cN}}{(1-e^{-c})\ln 2}}}$ , which at the ${\textstyle N\to \infty }$ limit is zero.

Thus the set of such ${\textstyle x}$ has Gauss measure zero.

Finish the estimate

Now, expand the term using basic continued fraction properties:

\ln \left|x-{\frac {p_{n}}{q_{n}}}\right|=\ln {\frac {T^{n}x}{q_{n}(q_{n}+q_{n-1}T^{n}x)}}=-2\ln q_{n}+\ln T^{n}x-\ln \left(1+{\frac {q_{n-1}}{q_{n}}}T^{n}x\right)

The second is ${\textstyle o(n)}$ . The third term is ${\textstyle \in [\ln 1,\ln 2]}$ . Both disappear after dividing by $n$ .
Thus

\lim _{n}{\frac {1}{n}}\ln \left|x-{\frac {p_{n}}{q_{n}}}\right|=-2\lim _{n}{\frac {1}{n}}\ln q_{n}=-{\frac {\pi ^{2}}{6\ln 2}}

where we used the result from Lévy's constant.

Related Research Articles

<span class="mw-page-title-main">Exponential function</span> Mathematical function, denoted exp(x) or e^x

The exponential function is a mathematical function denoted by $or . Unless otherwise specified, the term generally refers to the positive-valued function of a real variable, although it can be extended to the complex numbers or generalized to other mathematical objects like matrices or Lie algebras. The exponential function originated from the operation of taking powers of a number, but various modern definitions allow it to be rigorously extended to all real arguments, including irrational numbers. Its ubiquitous occurrence in pure and applied mathematics led mathematician Walter Rudin to consider the exponential function to be "the most important function in mathematics".$

In complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic on the whole complex plane. Typical examples of entire functions are polynomials and the exponential function, and any finite sums, products and compositions of these, such as the trigonometric functions sine and cosine and their hyperbolic counterparts sinh and cosh, as well as derivatives and integrals of entire functions such as the error function. If an entire function $has a root at, then, taking the limit value at, is an entire function. On the other hand, the natural logarithm, the reciprocal function, and the square root are all not entire functions, nor can they be continued analytically to an entire function.$

In mathematics, a series is, roughly speaking, the operation of adding infinitely many quantities, one after the other, to a given starting quantity. The study of series is a major part of calculus and its generalization, mathematical analysis. Series are used in most areas of mathematics, even for studying finite structures through generating functions. In addition to their ubiquity in mathematics, infinite series are also widely used in other quantitative disciplines such as physics, computer science, statistics and finance.

L'Hôpital's rule, also known as Bernoulli's rule, is a mathematical theorem that allows evaluating limits of indeterminate forms using derivatives. Application of the rule often converts an indeterminate form to an expression that can be easily evaluated by substitution. The rule is named after the 17th-century French mathematician Guillaume de l'Hôpital. Although the rule is often attributed to l'Hôpital, the theorem was first introduced to him in 1694 by the Swiss mathematician Johann Bernoulli.

In mathematics, a continued fraction is an expression obtained through an iterative process of representing a number as the sum of its integer part and the reciprocal of another number, then writing this other number as the sum of its integer part and another reciprocal, and so on. In a finite continued fraction, the iteration/recursion is terminated after finitely many steps by using an integer in lieu of another continued fraction. In contrast, an infinite continued fraction is an infinite expression. In either case, all integers in the sequence, other than the first, must be positive. The integers $are called the coefficients or terms of the continued fraction.$

In number theory, given a prime number $p$ , the $p$ -adic numbers form an extension of the rational numbers which is distinct from the real numbers, though with some similar properties; $p$ -adic numbers can be written in a form similar to decimals, but with digits based on a prime number $p$ rather than ten, and extending to the left rather than to the right. Formally, given a prime number $p$ , a $p$ -adic number can be defined as a series

In the mathematical field of real analysis, the monotone convergence theorem is any of a number of related theorems proving the convergence of monotonic sequences that are also bounded. Informally, the theorems state that if a sequence is increasing and bounded above by a supremum, then the sequence will converge to the supremum; in the same way, if a sequence is decreasing and is bounded below by an infimum, it will converge to the infimum.

In mathematics, the limit of a sequence is the value that the terms of a sequence "tend to", and is often denoted using the $symbol. If such a limit exists, the sequence is called convergent . A sequence that does not converge is said to be divergent . The limit of a sequence is said to be the fundamental notion on which the whole of mathematical analysis ultimately rests.$

In mathematics, the limit of a sequence of sets $is a set whose elements are determined by the sequence in either of two equivalent ways: (1) by upper and lower bounds on the sequence that converge monotonically to the same set and (2) by convergence of a sequence of indicator functions which are themselves real-valued. As is the case with sequences of other objects, convergence is not necessary or even usual.$

In mathematics, the ratio test is a test for the convergence of a series

In number theory, Aleksandr Yakovlevich Khinchin proved that for almost all real numbers x, coefficients a_i of the continued fraction expansion of x have a finite geometric mean that is independent of the value of x and is known as Khinchin's constant.

In mathematics, the integral test for convergence is a method used to test infinite series of monotonous terms for convergence. It was developed by Colin Maclaurin and Augustin-Louis Cauchy and is sometimes known as the Maclaurin–Cauchy test.

In mathematics, subadditivity is a property of a function that states, roughly, that evaluating the function for the sum of two elements of the domain always returns something less than or equal to the sum of the function's values at each element. There are numerous examples of subadditive functions in various areas of mathematics, particularly norms and square roots. Additive maps are special cases of subadditive functions.

In mathematics Lévy's constant occurs in an expression for the asymptotic behaviour of the denominators of the convergents of continued fractions. In 1935, the Soviet mathematician Aleksandr Khinchin showed that the denominators q_n of the convergents of the continued fraction expansions of almost all real numbers satisfy

In mathematics, the Mahler measure $of a polynomial with complex coefficients is defined as$

In mathematics, the Gauss–Kuzmin–Wirsing operator is the transfer operator of the Gauss map that takes a positive number to the fractional part of its reciprocal. It is named after Carl Gauss, Rodion Kuzmin, and Eduard Wirsing. It occurs in the study of continued fractions; it is also related to the Riemann zeta function.

<span class="mw-page-title-main">Gauss–Kuzmin distribution</span>

In mathematics, the Gauss–Kuzmin distribution is a discrete probability distribution that arises as the limit probability distribution of the coefficients in the continued fraction expansion of a random variable uniformly distributed in (0, 1). The distribution is named after Carl Friedrich Gauss, who derived it around 1800, and Rodion Kuzmin, who gave a bound on the rate of convergence in 1929. It is given by the probability mass function

In mathematics, the Kneser theorem can refer to two distinct theorems in the field of ordinary differential equations:

In extremal graph theory, the forbidden subgraph problem is the following problem: given a graph $, find the maximal number of edges an -vertex graph can have such that it does not have a subgraph isomorphic to . In this context, is called a forbidden subgraph .$

In mathematics, Kingman's subadditive ergodic theorem is one of several ergodic theorems. It can be seen as a generalization of Birkhoff's ergodic theorem. Intuitively, the subadditive ergodic theorem is a kind of random variable version of Fekete's lemma. As a result, it can be rephrased in the language of probability, e.g. using a sequence of random variables and expected values. The theorem is named after John Kingman.

References

↑ Lochs, Gustav (1964), "Vergleich der Genauigkeit von Dezimalbruch und Kettenbruch", Abhandlungen aus dem Mathematischen Seminar der Universität Hamburg (in German), 27 (1–2): 142–144, doi:10.1007/BF02993063, MR 0162753, S2CID 119419559
↑ Weisstein, Eric W. "Lochs' Theorem". MathWorld .
↑ Cooper, Harold (17 August 2016). "Continued Fraction Streams". Exist. Retrieved 30 August 2016.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Lochs, Gustav (1964), "Vergleich der Genauigkeit von Dezimalbruch und Kettenbruch", Abhandlungen aus dem Mathematischen Seminar der Universität Hamburg (in German), 27 (1–2): 142–144, doi:10.1007/BF02993063, MR 0162753, S2CID 119419559

[2] Weisstein, Eric W. "Lochs' Theorem". MathWorld .

[3] Cooper, Harold (17 August 2016). "Continued Fraction Streams". Exist. Retrieved 30 August 2016.

[1]

[2]

[3]