(OEIS A033307) is the number obtained by concatenating the positive integers and interpreting them as
decimal digits to the right of a decimal point. It is normal
in base 10 (Champernowne 1933, Bailey and Crandall 2002). Mahler (1961) showed it
to also be transcendental. The constant
has been computed to digits by E. W. Weisstein (Jul. 3,
2013) using the Wolfram Language.
The infinite sequence of digits in Champernowne's constant is sometimes known as Barbier's infinite word (Allouche and Shallit 2003, pp. 114, 299 and 334).
The number of digits after concatenation of the first, second, ... primes are given
by 1, 2, 3, 4, 6, 8, 10, 12, 14, 16, ... (OEIS A068670).
The Champernowne constant continued fraction contains sporadic very large terms, making the continued fraction difficult
to calculate. However, the size of the continued fraction high-water marks display
apparent patterns (Sikora 2012). Interestingly, the Copeland-Erdős
constant, which is the decimal number obtained by concatenating the primes
(instead of all the positive integers), has a well-behaved continued
fraction that does not show the "large term" phenomenon.
digits by E. W. Weisstein (Jul. 3,
2013) using the Wolfram Language.
Champernowne constant is implemented in the Wolfram
Language as ChampernowneNumber[b].
The base-2 and base-3 Champernowne constants are known as the binary
and ternary Champernowne constants,
respectively.
-ary Champernowne constant is given by
-ary Champernowne constant is given by
![sum_(k=b^(n-1))^(b^n-1)kb^(-n[k-(b^(n-1)-1)])](/https/mathworld.wolfram.com/images/equations/ChampernowneConstant/Inline7.svg)
in equation (3) is therefore
![S_n=(b^([b^n(n-bn+1)-b]/(b-1)))/((b^n-1)^2)[b(b^n-b^(2n)-1)
+(b^(2n)-b^n+b)b^(b(b-1)nb^(n-1))].](/https/mathworld.wolfram.com/images/equations/ChampernowneConstant/NumberedEquation4.svg)
to be computed directly from the base 
without explicit reference to the position of the terms.
Rytin, M. "Champernowne
Constant and Its Continued Fraction Expansion."