Defined in header <complex.h> | ||
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float complex cacoshf( float complex z ); | (1) | (since C99) |
double complex cacosh( double complex z ); | (2) | (since C99) |
long double complex cacoshl( long double complex z ); | (3) | (since C99) |
Defined in header <tgmath.h> | ||
#define acosh( z ) | (4) | (since C99) |
z with branch cut at values less than 1 along the real axis.z has type long double complex, cacoshl is called. if z has type double complex, cacosh is called, if z has type float complex, cacoshf is called. If z is real or integer, then the macro invokes the corresponding real function (acoshf, acosh, acoshl). If z is imaginary, then the macro invokes the corresponding complex number version and the return type is complex.| z | - | complex argument |
The complex arc hyperbolic cosine of z in the interval [0; ∞) along the real axis and in the interval [−iπ; +iπ] along the imaginary axis.
Errors are reported consistent with math_errhandling
If the implementation supports IEEE floating-point arithmetic,
cacosh(conj(z)) == conj(cacosh(z)) z is ±0+0i, the result is +0+iπ/2 z is +x+∞i (for any finite x), the result is +∞+iπ/2 z is +x+NaNi (for non-zero finite x), the result is NaN+NaNi and FE_INVALID may be raised. z is 0+NaNi, the result is NaN±iπ/2, where the sign of the imaginary part is unspecified z is -∞+yi (for any positive finite y), the result is +∞+iπ z is +∞+yi (for any positive finite y), the result is +∞+0i z is -∞+∞i, the result is +∞+3iπ/4 z is +∞+∞i, the result is +∞+iπ/4 z is ±∞+NaNi, the result is +∞+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 +∞+NaNi z is NaN+NaNi, the result is NaN+NaNi Although the C standard names this function "complex arc hyperbolic cosine", 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 cosine", and, less common, "complex area hyperbolic cosine".
Inverse hyperbolic cosine is a multivalued function and requires a branch cut on the complex plane. The branch cut is conventionally placed at the line segment (-∞,+1) of the real axis.
The mathematical definition of the principal value of the inverse hyperbolic cosine is acosh z = ln(z + √z+1 √z-1) For any z, acosh(z) =
√z-1/√1-z acos(z), or simply i acos(z) in the upper half of the complex plane.#include <stdio.h>
#include <complex.h>
int main(void)
{
double complex z = cacosh(0.5);
printf("cacosh(+0.5+0i) = %f%+fi\n", creal(z), cimag(z));
double complex z2 = conj(0.5); // or cacosh(CMPLX(0.5, -0.0)) in C11
printf("cacosh(+0.5-0i) (the other side of the cut) = %f%+fi\n", creal(z2), cimag(z2));
// in upper half-plane, acosh(z) = i*acos(z)
double complex z3 = casinh(1+I);
printf("casinh(1+1i) = %f%+fi\n", creal(z3), cimag(z3));
double complex z4 = I*casin(1+I);
printf("I*asin(1+1i) = %f%+fi\n", creal(z4), cimag(z4));
}Output:
cacosh(+0.5+0i) = 0.000000-1.047198i cacosh(+0.5-0i) (the other side of the cut) = 0.500000-0.000000i casinh(1+1i) = 1.061275+0.666239i I*asin(1+1i) = -1.061275+0.666239i
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(C99)(C99)(C99) | computes the complex arc cosine (function) |
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(C99)(C99)(C99) | computes the complex arc hyperbolic sine (function) |
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(C99)(C99)(C99) | computes the complex arc hyperbolic tangent (function) |
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(C99)(C99)(C99) | computes the complex hyperbolic cosine (function) |
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(C99)(C99)(C99) | computes inverse hyperbolic cosine (\({\small\operatorname{arcosh}{x} }\)arcosh(x)) (function) |
C++ documentation for acosh |
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