Defined in header <complex.h> | ||
---|---|---|
float complex catanhf( float complex z ); | (1) | (since C99) |
double complex catanh( double complex z ); | (2) | (since C99) |
long double complex catanhl( long double complex z ); | (3) | (since C99) |
Defined in header <tgmath.h> | ||
#define atanh( z ) | (4) | (since C99) |
z
with branch cuts outside the interval [−1; +1] along the real axis.z
has type long double complex
, catanhl
is called. if z
has type double complex
, catanh
is called, if z
has type float complex
, catanhf
is called. If z
is real or integer, then the macro invokes the corresponding real function (atanhf
, atanh
, atanhl
). If z
is imaginary, then the macro invokes the corresponding real version of atan
, implementing the formula atanh(iy) = i atan(y), and the return type is imaginary.z | - | complex argument |
If no errors occur, the complex arc hyperbolic tangent of z
is returned, in the range of a half-strip mathematically unbounded along the real axis and in the interval [−iπ/2; +iπ/2] along the imaginary axis.
Errors are reported consistent with math_errhandling.
If the implementation supports IEEE floating-point arithmetic,
catanh(conj(z)) == conj(catanh(z))
catanh(-z) == -catanh(z)
z
is +0+0i
, the result is +0+0i
z
is +0+NaNi
, the result is +0+NaNi
z
is +1+0i
, the result is +∞+0i
and FE_DIVBYZERO
is raised z
is x+∞i
(for any finite positive x), the result is +0+iπ/2
z
is x+NaNi
(for any finite nonzero x), the result is NaN+NaNi
and FE_INVALID
may be raised z
is +∞+yi
(for any finite positive y), the result is +0+iπ/2
z
is +∞+∞i
, the result is +0+iπ/2
z
is +∞+NaNi
, the result is +0+NaNi
z
is NaN+yi
(for any finite y), the result is NaN+NaNi
and FE_INVALID
may be raised z
is NaN+∞i
, the result is ±0+iπ/2
(the sign of the real part is unspecified) z
is NaN+NaNi
, the result is NaN+NaNi
Although the C standard names this function "complex arc hyperbolic tangent", the inverse functions of the hyperbolic functions are the area functions. Their argument is the area of a hyperbolic sector, not an arc. The correct name is "complex inverse hyperbolic tangent", and, less common, "complex area hyperbolic tangent".
Inverse hyperbolic tangent is a multivalued function and requires a branch cut on the complex plane. The branch cut is conventionally placed at the line segmentd (-∞,-1] and [+1,+∞) of the real axis. The mathematical definition of the principal value of the inverse hyperbolic sine is atanh z =
ln(1+z)-ln(z-1) |
2 |
For any z, atanh(z) =
atan(iz) |
i |
#include <stdio.h> #include <complex.h> int main(void) { double complex z = catanh(2); printf("catanh(+2+0i) = %f%+fi\n", creal(z), cimag(z)); double complex z2 = catanh(conj(2)); // or catanh(CMPLX(2, -0.0)) in C11 printf("catanh(+2-0i) (the other side of the cut) = %f%+fi\n", creal(z2), cimag(z2)); // for any z, atanh(z) = atan(iz)/i double complex z3 = catanh(1+2*I); printf("catanh(1+2i) = %f%+fi\n", creal(z3), cimag(z3)); double complex z4 = catan((1+2*I)*I)/I; printf("catan(i * (1+2i))/i = %f%+fi\n", creal(z4), cimag(z4)); }
Output:
catanh(+2+0i) = 0.549306+1.570796i catanh(+2-0i) (the other side of the cut) = 0.549306-1.570796i catanh(1+2i) = 0.173287+1.178097i catan(i * (1+2i))/i = 0.173287+1.178097i
(C99)(C99)(C99) | computes the complex arc hyperbolic sine (function) |
(C99)(C99)(C99) | computes the complex arc hyperbolic cosine (function) |
(C99)(C99)(C99) | computes the complex hyperbolic tangent (function) |
(C99)(C99)(C99) | computes inverse hyperbolic tangent (artanh(x)) (function) |
C++ documentation for atanh |
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