acosh#

ivy.acosh(x, /, *, out=None)[source]#

Calculate an implementation-dependent approximation to the inverse hyperbolic cosine, having domain [+1, +infinity] and codomain [+0, +infinity], for each element x_i of the input array x.

Special cases

For floating-point operands,

  • If x_i is NaN, the result is NaN.

  • If x_i is less than 1, the result is NaN.

  • If x_i is 1, the result is +0.

  • If x_i is +infinity, the result is +infinity.

For complex floating-point operands, let a = real(x_i) and b = imag(x_i), and

  • If a is either +0 or -0 and b is +0, the result is +0 + πj/2.

  • If a is a finite number and b is +infinity, the result is +infinity + πj/2.

  • If a is a nonzero finite number and b is NaN, the result is NaN + NaN j.

  • If a is +0 and b is NaN, the result is NaN ± πj/2 (sign of the imaginary component is unspecified).

  • If a is -infinity and b is a positive (i.e., greater than 0) finite number, the result is +infinity + πj.

  • If a is +infinity and b is a positive (i.e., greater than 0) finite number, the result is +infinity + 0j.

  • If a is -infinity and b is +infinity, the result is +infinity + 3πj/4.

  • If a is +infinity and b is +infinity, the result is +infinity + πj/4.

  • If a is either +infinity or -infinity and b is NaN, the result is +infinity + NaN j.

  • If a is NaN and b is a finite number, the result is NaN + NaN j.

  • if a is NaN and b is +infinity, the result is +infinity + NaN j.

  • If a is NaN and b is NaN, the result is NaN + NaN j.

Parameters:
  • x (Union[Array, NativeArray]) – input array whose elements each represent the area of a hyperbolic sector. Should have a floating-point data type.

  • out (Optional[Array], default: None) – optional output array, for writing the result to. It must have a shape that the inputs broadcast to.

Return type:

Array

Returns:

ret – an array containing the inverse hyperbolic cosine of each element in x. The returned array must have a floating-point data type determined by type-promotion.

This function conforms to the Array API Standard. This docstring is an extension of the docstring in the standard.

Both the description and the type hints above assumes an array input for simplicity, but this function is nestable, and therefore also accepts ivy.Container instances in place of any of the arguments

Examples

With ivy.Array input:

>>> x = ivy.array([1, 2.5, 10])
>>> y = ivy.acosh(x)
>>> print(y)
ivy.array([0.  , 1.57, 2.99])
>>> x = ivy.array([1., 2., 6.])
>>> y = ivy.zeros(3)
>>> ivy.acosh(x, out=y)
>>> print(y)
ivy.array([0.  , 1.32, 2.48])

With ivy.Container input:

>>> x = ivy.Container(a=ivy.array([1., 2., 10.]), b=ivy.array([1., 10., 6.]))
>>> y = ivy.acosh(x)
>>> print(y)
{
    a: ivy.array([0., 1.32, 2.99]),
    b: ivy.array([0., 2.99, 2.48])
}
Array.acosh(self, *, out=None)[source]#

ivy.Array instance method variant of ivy.acosh. This method simply wraps the function, and so the docstring for ivy.acosh also applies to this method with minimal changes.

Parameters:
  • self (Array) – input array whose elements each represent the area of a hyperbolic sector. Should have a real-valued floating-point data type.

  • out (Optional[Array], default: None) – optional output array, for writing the result to. It must have a shape that the inputs broadcast to.

Return type:

Array

Returns:

ret – an array containing the inverse hyperbolic cosine of each element in self. The returned array must have the same data type as self.

Examples

>>> x = ivy.array([2., 10.0, 1.0])
>>> y = x.acosh()
>>> print(y)
ivy.array([1.32, 2.99, 0.  ])
Container.acosh(self, *, key_chains=None, to_apply=True, prune_unapplied=False, map_sequences=False, out=None)[source]#

ivy.Container instance method variant of ivy.acosh. This method simply wraps the function, and so the docstring for ivy.acosh also applies to this method with minimal changes.

Parameters:
  • self (Container) – input container whose elements each represent the area of a hyperbolic sector. Should have a floating-point data type.

  • key_chains (Optional[Union[List[str], Dict[str, str], Container]], default: None) – The key-chains to apply or not apply the method to. Default is None.

  • to_apply (Union[bool, Container], default: True) – If True, the method will be applied to key_chains, otherwise key_chains will be skipped. Default is True.

  • prune_unapplied (Union[bool, Container], default: False) – Whether to prune key_chains for which the function was not applied. Default is False.

  • map_sequences (Union[bool, Container], default: False) – Whether to also map method to sequences (lists, tuples). Default is False.

  • out (Optional[Container], default: None) – optional output container, for writing the result to. It must have a shape that the inputs broadcast to.

Return type:

Container

Returns:

ret – a container containing the inverse hyperbolic cosine of each element in self. The returned container must have a floating-point data type determined by type-promotion.

Examples

>>> x = ivy.Container(a=ivy.array([1., 2., 3, 4]),
...                   b=ivy.array([1., 3., 10.0, 6]))
>>> y = x.acosh()
>>> print(y)
{
    a: ivy.array([0., 1.32, 1.76, 2.06]),
    b: ivy.array([0., 1.76, 2.99, 2.48])
}