Prime constant

The prime constant is the real number $\rho$ whose $n$ th binary digit is 1 if $n$ is prime and 0 if $n$ is composite or 1.

In other words, $\rho$ is the number whose binary expansion corresponds to the indicator function of the set of prime numbers. That is,

\rho =\sum _{p}{\frac {1}{2^{p}}}=\sum _{n=1}^{\infty }{\frac {\chi _{\mathbb {P} }(n)}{2^{n}}}

where $p$ indicates a prime and $\chi _{\mathbb {P} }$ is the characteristic function of the set $\mathbb {P}$ of prime numbers.

The beginning of the decimal expansion of ρ is: $\rho =0.414682509851111660248109622\ldots$ (sequence A051006 in the OEIS)

The beginning of the binary expansion is: $\rho =0.011010100010100010100010000\ldots _{2}$ (sequence A010051 in the OEIS)

Irrationality[edit]

The number $\rho$ can be shown to be irrational.^[1] To see why, suppose it were rational.

Denote the $k$ th digit of the binary expansion of $\rho$ by $r_{k}$ . Then since $\rho$ is assumed rational, its binary expansion is eventually periodic, and so there exist positive integers $N$ and $k$ such that $r_{n}=r_{n+ik}$ for all $n>N$ and all $i\in \mathbb {N}$ .

Since there are an infinite number of primes, we may choose a prime $p>N$ . By definition we see that $r_{p}=1$ . As noted, we have $r_{p}=r_{p+ik}$ for all $i\in \mathbb {N}$ . Now consider the case $i=p$ . We have $r_{p+i\cdot k}=r_{p+p\cdot k}=r_{p(k+1)}=0$ , since $p(k+1)$ is composite because $k+1\geq 2$ . Since $r_{p}\neq r_{p(k+1)}$ we see that $\rho$ is irrational.

References[edit]

^ Hardy, G. H. (2008). An introduction to the theory of numbers. E. M. Wright, D. R. Heath-Brown, Joseph H. Silverman (6th ed.). Oxford: Oxford University Press. ISBN 978-0-19-921985-8. OCLC 214305907.

External links[edit]

Weisstein, Eric W. "Prime Constant". MathWorld.

[1] Hardy, G. H. (2008). An introduction to the theory of numbers. E. M. Wright, D. R. Heath-Brown, Joseph H. Silverman (6th ed.). Oxford: Oxford University Press. ISBN 978-0-19-921985-8. OCLC 214305907.

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