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- acos
- acosd
- acosh
- acoshm
- acosm
- acot
- acotd
- acoth
- acsc
- acscd
- acsch
- asec
- asecd
- asech
- asin
- asind
- asinh
- asinhm
- asinm
- atan
- atand
- atanh
- atanhm
- atanm
- cos
- cosd
- cosh
- coshm
- cosm
- cotd
- cotg
- coth
- cothm
- csc
- cscd
- csch
- csgn
- sec
- secd
- sech
- sin
- sinc
- sind
- sinh
- sinhm
- sinm
- tan
- tand
- tanh
- tanhm
- tanm
Please note that the recommended version of Scilab is 2025.0.0. This page might be outdated.
See the recommended documentation of this function
atanh
hyperbolic tangent inverse
Syntax
t = atanh(x)
Arguments
- x
a real or complex vector/matrix.
- t
a real or complex vector/matrix.
Description
The components of vector t
are the hyperbolic
tangent inverse of the corresponding entries of vector
x
. Definition domain is [-1,1]
for
the real function (see Remark).
Remark
In Scilab (as in some others numerical software) when you try to
evaluate an elementary mathematical function outside its definition domain
in the real case, then the complex extension is used (with a complex
result). The most famous example being the sqrt
function (try
sqrt(-1)
!). This approach have some drawbacks when you
evaluate the function at a singular point which may led to different
results when the point is considered as real or complex. For the
atanh
this occurs for -1
and
1
because the at these points the imaginary part do not
converge and so atanh(1) = +Inf + i NaN
while
atanh(1) = +Inf
for the real case (as lim x->1
of
atanh(x)
). So when you evaluate this function on the vector [1 2]
then like 2
is outside the definition
domain, the complex extension is used for all the vector and you get
atanh(1) = +Inf + i NaN
while you get atanh(1)
= +Inf
with [1 0.5]
for instance.
Examples
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