Random and pseudo-random numbers
Numbers $ \xi _ {n} $(
in particular, binary digits $ \alpha _ {n} $)
whose sequential appearance satisfies some kind of statistical regularity (see Probability theory). One distinguishes random numbers, being generated by a stochastic apparatus, and pseudo-random numbers, being constructed using arithmetical algorithms. It is usually assumed (for better or worse reason) that the sequence obtained (or constructed) has frequency properties that are "typical" for a sequence of independent realizations of some random variable $ \xi $
with distribution function $ F ( z) $;
then one speaks of (independent) random numbers distributed according to the law $ F ( z) $.
The most commonly used examples are as follows: random numbers $ \xi _ {n} $
uniformly distributed on the interval $ [ 0 , 1 ] $,
$ {\mathsf P} ( \xi _ {n} < x ) = x $,
equi-probable random binary digits $ \alpha _ {n} $,
$ {\mathsf P} \{ \alpha _ {n} = 0 \} = {\mathsf P} \{ \alpha _ {n} = 1 \} = 1/2 $,
and random normal numbers $ \eta _ {n} $
distributed according to the normal law with mean $ 0 $
and variance 1 (cf. Uniform distribution; Normal distribution). Random numbers $ \zeta _ {n} $
with an arbitrary distribution function $ F ( z) $
can be constructed from a sequence of uniformly-distributed random numbers $ \xi _ {n} $
by putting $ \xi _ {n} = F ^ { - 1 } ( \zeta _ {n} ) $,
that is, they can be found from the equation $ \zeta _ {n} = F ( \xi _ {n} ) $,
$ n = 1 , 2 ,\dots $.
There are also other methods of construction: for example, it is analytically simpler to obtain normally-distributed random numbers from uniformly-distributed random numbers by using the pairs
$$ \zeta _ {2 n - 1 } = \ \sqrt {- 2 \mathop{\rm ln} \xi _ {2n} } \cos 2 \pi \xi _ {2 n - 1 } , $$
$$ \zeta _ {2n} = \sqrt {- 2 \mathop{\rm ln} \xi _ {2n} } \sin 2 \pi \xi _ {2 n - 1 } . $$
The digits of uniformly-distributed random numbers in binary notation are equi-probable random binary digits; conversely, by grouping equi-probable random binary digits into infinite sequences one obtains uniformly-distributed random numbers.
Random and pseudo-random numbers are used in practice in the theory of games (cf. Games, theory of), in mathematical statistics, in Monte-Carlo methods (cf. Monte-Carlo method), and in cryptography, for the concrete realization of non-determined algorithms and behaviour predicted only "on the average" . For example, if the next $ \alpha _ {n} = 0 $, then a player chooses the first strategy, but if $ \alpha _ {n} = 1 $, then he/she takes the second.
It is only possible to attach a strict mathematical sense to the concept of random numbers in the framework of the algorithmic probability theory of A.N. Kolmogorov [2] and P. Martin-Löf [5]. Let $ H = \times _ {n=} 1 ^ \infty \{ {x _ {n} } : {0 \leq x _ {n} \leq 1 } \} $ be the countably-dimensional unit hypercube, let $ \lambda $ be the Lebesgue measure on $ H $ and let $ G \subset H $ be a largest constructively-described measurable set of measure zero (it exists). Then any sequence $ \{ x _ {n} \} \notin G $ can be regarded as typical, and so taken as a sequence of uniformly-distributed random numbers. Similarly one can introduce the concept of constructive $ ( \epsilon , l ) $- typicality of an $ N $- sequence of binary symbols $ a _ {j} $, $ j = 1 \dots N $, with respect to the system of all events $ B \subset \{ 0 ; 1 \} ^ {N} $: to be of measure not more than $ \epsilon $ and of length of description not more than $ l $. It is evident from the definition that a typical sequence of uniformly-distributed random numbers cannot itself be constructive, and even the construction of an $ ( \epsilon , l ) $- typical sequence of random symbols requires an extraordinary large search. Therefore, in practice one uses simpler algorithms, allowing checking of their statistical "quality" with a few tests. Thus, in constructing uniformly-distributed random numbers one must necessarily test the uniform distribution of the sequence (see [3]). In simple problems, the fulfillment of certain tests can actually guarantee the usefulness of a sequence. It is sometimes more effective to use correlated random numbers, constructed from a sequence of uniformly-distributed random numbers.
Tables of random numbers and random digits have been published. However, it appears to be impossible to guarantee that they satisfy all reasonable statistical tests for non-correlation.
References
[1] | S.M. Ermakov, "Die Monte-Carlo Methode und verwandte Fragen" , Deutsch. Verlag Wissenschaft. (1975) (Translated from Russian) |
[2] | A.N. Kolmogorov, "On tables of random numbers" Sankhya Ser. A , 25 (1963) pp. 369–376 |
[3] | N.M. Korobov, "On some questions of uniform distribution" Izv. Akad. Nauk SSSR , 14 : 3 (1950) pp. 215–238 (In Russian) |
[4] | D. Knuth, "The art of computer programming" , 2 , Addison-Wesley (1969) |
[5] | P. Martin-Löf, "The definition of random sequences" Inform. and Control , 9 (1966) pp. 602–619 |
[6] | N.N. Chentsov, "Pseudo-random numbers for simulation of Markov chains" Zh. Vychisl. Mat. i Mat. Fiz. , 7 : 3 (1967) pp. 632–643 |
[7] | A. Shen', "Frequency approach to the definition of the notion of random sequence" Semiotika i Informatika , 18 (1982) pp. 14–42 (In Russian) |
Comments
References
[a1] | P. Bratley, B.L. Fox, L.E. Schrage, "A guide to simulation" , Springer (1987) |
Random and pseudo-random numbers. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Random_and_pseudo-random_numbers&oldid=14692