Wolfram Researchfunctions.wolfram.comOther Wolfram Sites
Search Site
Function CategoriesGraphics GalleryNotationsGeneral IdentitiesAbout This Site Email Comments

View Related Information In
The Documentation Center
MathWorld

Download All Formulas For This Function
Mathematica Notebook
PDF File

Download All Introductions For This Function
Mathematica Notebook
PDF File

 

Developed with Mathematica -- Download a Free Trial Version
 











Cosh






Mathematica Notation

Traditional Notation









Elementary Functions > Cosh[z] > Introduction to the hyperbolic functions





The best-known properties and formulas for hyperbolic functions


For real values of argument , the values of all the hyperbolic functions are real (or infinity).

In the points , the values of the hyperbolic functions are algebraic. In several cases, they can even be rational numbers, , or (e.g. , , or ). They 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, …}.

All hyperbolic functions has rather simple values for arguments and :

All hyperbolic functions are defined for all complex values of , and they are analytical functions of over the whole complex ‐plane and do not have branch cuts or branch points. The two functions and are entire functions with an essential singular point at . All other hyperbolic functions are meromorphic functions with simple poles at points (for and ) and at points (for and ).

All hyperbolic functions are periodic functions with a real period ( or ):

All hyperbolic functions have parity (either odd or even) and mirror symmetry:

The derivatives of all hyperbolic functions have simple representations that can be expressed through other hyperbolic functions:

The solutions of the simplest second‐order linear ordinary differential equation with constant coefficients can be represented through and . The other hyperbolic functions satisfy first‐order nonlinear differential equations:

All six hyperbolic functions satisfy first‐order nonlinear differential equations: