Lobachevskii function

Angle of parallelism

The angle of parallelism in Lobachevskii geometry is a function that expresses the angle $ \alpha $ between the line $ u _ {1} $ (or $ u _ {2} $) (see Fig.) and the segment $ OA $ perpendicular to a line $ a $ parallel to $ u _ {1} $( or $ u _ {2} $) in terms of the length $ l $ of the segment $ OA $:

$$ \alpha = \Pi(l) = 2 { \mathop{\rm arc} \mathop{\rm tan} } e ^ {- l / R } , $$

where $R$ is a positive constant that corresponds to the scale of measurement of distances.

Figure: l060020a

The Lobachevskii function is a continuous monotone decreasing function with values between $\pi/2$ and 0:

$$ \lim\limits _ {l \rightarrow 0 } \Pi ( l) = \frac \pi {2} ,\ \lim\limits _ { l \rightarrow \infty } \Pi ( l) = 0. $$

It was introduced by N.I. Lobachevskii in 1826.

Second meaning

The special function (cf. Special functions) defined for real $x$ by

$$ L(x) = - \int\limits_{0}^{x} \mathop{\rm ln} \cos t dt . $$

The Lobachevskii function can be represented as a series

$$ L(x) = x \mathop{\rm ln} 2 - \frac{1}{2} \sum _ { k= 1} ^ {\infty } (- 1) ^ {k- 1} \frac{\sin 2kx }{k ^ {2} } . $$

The main relations are:

$$ L ( - x ) = - L ( x) ,\ - \frac \pi {2} \leq x \leq \frac \pi {2}, $$

$$ L ( \pi - x ) = \pi \mathop{\rm ln} 2 - L ( x) , $$

$$ L ( \pi + x ) = \pi \mathop{\rm ln} 2 + L ( x) . $$

It was introduced by N.I. Lobachevskii in 1829.

Comments

For the Lobachevskii function in the sense of 1) (i.e. the angle of parallelism) see also [a1]–[a4].

For Lobachevskii's function as defined in 2) see also [a5].

References