ctanhf, ctanh, ctanhl

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< c‎ | numeric‎ | complex
Defined in header <complex.h>
float complex       ctanhf( float complex z );
(1) (since C99)
double complex      ctanh( double complex z );
(2) (since C99)
long double complex ctanhl( long double complex z );
(3) (since C99)
Defined in header <tgmath.h>
#define tanh( z )
(4) (since C99)
1-3) Computes the complex hyperbolic tangent of z.
4) Type-generic macro: If z has type long double complex, ctanhl is called. if z has type double complex, ctanh is called, if z has type float complex, ctanhf is called. If z is real or integer, then the macro invokes the corresponding real function (tanhf, tanh, tanhl). If z is imaginary, then the macro invokes the corresponding real version of the function tan, implementing the formula tanh(iy) = i tan(y), and the return type is imaginary.

Contents

[edit] Parameters

z - complex argument

[edit] Return value

If no errors occur, complex hyperbolic tangent of z is returned

[edit] Error handling and special values

Errors are reported consistent with math_errhandling

If the implementation supports IEEE floating-point arithmetic,

  • ctanh(conj(z)) == conj(ctanh(z))
  • ctanh(-z) == -ctanh(z)
  • If z is +0+0i, the result is +0+0i
  • If z is x+∞i (for any finite x), the result is NaN+NaNi and FE_INVALID is raised
  • If z is x+NaN (for any finite x), the result is NaN+NaNi and FE_INVALID may be raised
  • If z is +∞+yi (for any finite positive y), the result is 1+0i
  • If z is +∞+∞i, the result is 1±0i (the sign of the imaginary part is unspecified)
  • If z is +∞+NaNi, the result is 1±0i (the sign of the imaginary part is unspecified)
  • If z is NaN+0i, the result is NaN+0i
  • If z is NaN+yi (for any non-zero y), the result is NaN+NaNi and FE_INVALID may be raised
  • If z is NaN+NaNi, the result is NaN+NaNi

[edit] Notes

Mathematical definition of hyperbolic tangent is cosh z =
ez
-e-z
ez
+e-z

Hyperbolic tangent is an analytical function on the complex plain and has no branch cuts. It is periodic with respect to the imaginary component, with period πi, and has poles of the first order along the imaginary line, at coordinates (0, π(1/2 + n)). However no common floating-point representation is able to represent π/2 exactly, thus there is no value of the argument for which a pole error occurs.

[edit] Example

#include <stdio.h>
#include <math.h>
#include <complex.h>
 
int main(void)
{
    double complex z = ctanh(1);  // behaves like real tanh along the real line
    printf("tanh(1+0i) = %f%+fi (tanh(1)=%f)\n", creal(z), cimag(z), tanh(1));
 
    double complex z2 = ctanh(I); // behaves like tangent along the imaginary line
    printf("tanh(0+1i) = %f%+fi ( tan(1)=%f)\n", creal(z2), cimag(z2), tan(1));
}

Output:

tanh(1+0i) = 0.761594+0.000000i (tanh(1)=0.761594)
tanh(0+1i) = 0.000000+1.557408i ( tan(1)=1.557408)

[edit] See also

(C99)(C99)(C99)
computes the complex hyperbolic sine
(function)
(C99)(C99)(C99)
computes the complex hyperbolic cosine
(function)
(C99)(C99)(C99)
computes the complex arc hyperbolic tangent
(function)
(C99)(C99)
computes hyperbolic tangent
(function)