Wallis formula

A formula which expresses the number $ \pi /2 $ as an infinite product:

$$ \tag{1 } { \frac \pi {2} } = \ \left ( { \frac{2}{1} } \cdot { \frac{2}{3} } \right ) \left ( { \frac{4}{3} } \cdot { \frac{4}{5} } \right ) \dots \left ( { \frac{2k}{2k-} 1 } \cdot { \frac{2k}{2k+} 1 } \right ) \dots = $$

$$ = \ \lim\limits _ {m \rightarrow \infty } \prod _ { k= } 1 ^ { m } \frac{( 2k) ^ {2} }{( 2k- 1)( 2k+ 1) } . $$

There exist other variants of this formula, e.g.:

$$ \tag{2 } \sqrt \pi = \ \lim\limits _ {m \rightarrow \infty } \ \frac{( m!) ^ {2} \cdot 2 ^ {2m} }{( 2m)! \sqrt m } . $$

Formula (1) was first employed by J. Wallis [1] in his calculation of the area of a disc; it is one of the earliest examples of an infinite product.

References

Comments

Formula (1) is a direct consequence of Euler's product formula

$$ \sin z = z \prod _ { n= } 1 ^ \infty \left ( 1 - \frac{z ^ {2} }{n ^ {2} \pi ^ {2} } \right ) $$

with $ \pi /2 $.

It can also be obtained by expressing $ \int _ {0} ^ {\pi /2 } \sin ^ {2m} x dx $ and $ \int _ {0} ^ {\pi /2 } \sin ^ {2m+} 1 x dx $ in terms of $ m $, and by showing that

$$ \frac{\int\limits _ { 0 } ^ { \pi /2 } \sin ^ {2m} x dx }{\int\limits _ { 0 } ^ { \pi /2 } \sin ^ {2m+} 1 x dx } \rightarrow 1 \ ( m\rightarrow \infty ). $$

Formula (2) can be derived from (1) by multiplying the numerator and the denominator of $ \prod _ {k=} 1 ^ {m} ( 2k) ^ {2} / ( 2k- 1)( 2k+ 1) $ by $ 2 ^ {2} \cdot 4 ^ {2} \dots ( 2m) ^ {2} $.

References