- #1
lfdahl
Gold Member
MHB
- 749
- 0
Evaluate:
$$\prod_{n=1}^{\infty}\left(1+10^{-2^n}\right)$$
$$\prod_{n=1}^{\infty}\left(1+10^{-2^n}\right)$$
lfdahl said:Evaluate:
$$\prod_{n=1}^{\infty}\left(1+10^{-2^n}\right)$$
kaliprasad said:Llet $x=\prod_{n=1}^{\infty}
(1+10^{-2^n})$
Using $(1-10^{-2^n})(1+10^{-2^n}) = (1+10^{-2^{n+1}})$
We have
$x(1-10^{-2^1})=(1-10^{-2^1})\prod_{n=1}^{\infty}(1+10^{-2^n})$
$=(1-10^{-2^2})\prod_{n=2}^{\infty}(1+10^{-2^n})$
$=\lim{n=\infty}(1+10^{-2^n}) = 1$
or x * .99 = 1 or $x = \frac{1}{.99}=\frac{100}{99}$
The purpose of evaluating this product is to determine the value of the infinite product as n approaches infinity. It is a common mathematical problem that is used in various fields, such as number theory and complex analysis.
The product can be evaluated using a mathematical formula known as the Euler product formula, which states that ∏(1+10^(-2^n)) is equal to the reciprocal of the Riemann zeta function evaluated at 2. This can also be done numerically using a computer or calculator.
The product has various applications in mathematics, including in number theory, complex analysis, and fractal geometry. It is also used in cryptography and coding theory.
No, there is no known closed form solution for this product. It can only be expressed using the Euler product formula or evaluated numerically.
Yes, the product can be simplified using various mathematical techniques, such as the Euler product formula or the use of logarithms. It can also be approximated using numerical methods, such as the use of Taylor series or computer algorithms.