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The values of the hyperbolic cosecant function for special values of its argument can be easily derived from the corresponding values of the circular cosecant in the special points of the circle:
The values at infinity can be expressed by the following formulas:
For real values of argument  , the values of  are real.
In the points  , the values of  are algebraic. In several cases, they can be  ,  ,  , or  :
The values of  can be expressed using only square roots if  and  is a product of a power of 2 and distinct Fermat primes {3, 5, 17, 257, …}.
The function  is an analytical function of  that is defined over the whole complex  ‐plane and does not have branch cuts and branch points. It has an infinite set of singular points:
(a)  are the simple poles with residues  .
(b)  is an essential singular point.
It is a periodic function with period  :
The function  is an odd function with mirror symmetry:
The first derivative of  has simple representations using either the  function or the  function:
The   derivative of  has much more complicated representations than the symbolic   derivatives for  and  :
where  is the Kronecker delta symbol:  and  .
The functions  satisfies the following first‐order nonlinear differential equation:
The function  has the following Laurent series expansion at the origin that converges for all finite values  with  :
where  are the Bernoulli numbers.
The hyperbolic cosecant function  can also be represented using other kinds of series by the following formulas:
The function  has a well-known integral representation through the following definite integral along the positive part of the real axis:
The famous infinite product representation for  can be easily rewritten as the following product representation for the hyperbolic cosecant function:
The hyperbolic cosecant function has the following limit representation:
Indefinite integrals of expressions involving the hyperbolic cosecant function can sometimes be expressed using elementary functions. However, special functions are frequently needed to express the results even when the integrands have a simple form (if they can be evaluated in closed form). Here are some examples:
Definite integrals that contain the hyperbolic cosecant function are sometimes simple. Here is an example:
Some special functions can be used to evaluate more complicated definite integrals. For example, zeta and polylogarithmic functions are needed to express the following integrals:
The following finite sum that contains the hyperbolic cosecant has this simple value:
The following infinite sum that contains the hyperbolic cosecant has this simple value:
where  is the inverse elliptic nome.
The hyperbolic cosecant of a sum or difference can be represented in terms of the hyperbolic sine and cosine as shown in the following formulas:
In the case of multiple arguments  ,  , …, the function  can be represented as a rational function that contains powers of the hyperbolic cosecants and secants. Here are two examples:
The hyperbolic cosecant of a half‐angle can be represented by the following simple formula that is valid in a horizontal half‐strip:
This formula can be expanded to the full horizontal strip if an additional regulator of the sign is added:
To make this formula correct for all complex  , a more complicated prefactor is needed:
where  contains the unit step, real part, imaginary part, and the floor functions.
The sum and difference of two hyperbolic cosecant functions can be described by the following formulas:
The product of two hyperbolic cosecants and the product of the hyperbolic cosecant and secant have the following representations:
One of the most famous inequalities for the hyperbolic cosecant function is the following:
There are simple relations between the function  and its inverse function  :
The second formula is valid at least in the horizontal strip  . Outside of this strip a much more complicated relation (that contains the unit step, real part, and the floor functions) holds:
The hyperbolic cosecant and secant functions are connected by a very simple formula that includes the linear function in the argument:
The hyperbolic cosecant function can also be represented using other hyperbolic functions by the following formulas:
The hyperbolic cosecant function has the following representations using the trigonometric functions:
The hyperbolic cosecant function is used throughout mathematics, the exact sciences, and engineering.
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