cmath — Mathematical functions for complex numbers


This module provides access to mathematical functions for complex numbers. The functions in this module accept integers, floating-point numbers or complex numbers as arguments. They will also accept any Python object that has either a __complex__() or a __float__() method: these methods are used to convert the object to a complex or floating-point number, respectively, and the function is then applied to the result of the conversion.

Informacja

For functions involving branch cuts, we have the problem of deciding how to define those functions on the cut itself. Following Kahan’s „Branch cuts for complex elementary functions” paper, as well as Annex G of C99 and later C standards, we use the sign of zero to distinguish one side of the branch cut from the other: for a branch cut along (a portion of) the real axis we look at the sign of the imaginary part, while for a branch cut along the imaginary axis we look at the sign of the real part.

For example, the cmath.sqrt() function has a branch cut along the negative real axis. An argument of complex(-2.0, -0.0) is treated as though it lies below the branch cut, and so gives a result on the negative imaginary axis:

>>> cmath.sqrt(complex(-2.0, -0.0))
-1.4142135623730951j

But an argument of complex(-2.0, 0.0) is treated as though it lies above the branch cut:

>>> cmath.sqrt(complex(-2.0, 0.0))
1.4142135623730951j

Conversions to and from polar coordinates

A Python complex number z is stored internally using rectangular or Cartesian coordinates. It is completely determined by its real part z.real and its imaginary part z.imag.

Polar coordinates give an alternative way to represent a complex number. In polar coordinates, a complex number z is defined by the modulus r and the phase angle phi. The modulus r is the distance from z to the origin, while the phase phi is the counterclockwise angle, measured in radians, from the positive x-axis to the line segment that joins the origin to z.

The following functions can be used to convert from the native rectangular coordinates to polar coordinates and back.

cmath.phase(x)

Return the phase of x (also known as the argument of x), as a float. phase(x) is equivalent to math.atan2(x.imag, x.real). The result lies in the range [-π, π], and the branch cut for this operation lies along the negative real axis. The sign of the result is the same as the sign of x.imag, even when x.imag is zero:

>>> phase(complex(-1.0, 0.0))
3.141592653589793
>>> phase(complex(-1.0, -0.0))
-3.141592653589793

Informacja

The modulus (absolute value) of a complex number x can be computed using the built-in abs() function. There is no separate cmath module function for this operation.

cmath.polar(x)

Return the representation of x in polar coordinates. Returns a pair (r, phi) where r is the modulus of x and phi is the phase of x. polar(x) is equivalent to (abs(x), phase(x)).

cmath.rect(r, phi)

Return the complex number x with polar coordinates r and phi. Equivalent to complex(r * math.cos(phi), r * math.sin(phi)).

Power and logarithmic functions

cmath.exp(x)

Return e raised to the power x, where e is the base of natural logarithms.

cmath.log(x[, base])

Returns the logarithm of x to the given base. If the base is not specified, returns the natural logarithm of x. There is one branch cut, from 0 along the negative real axis to -∞.

cmath.log10(x)

Return the base-10 logarithm of x. This has the same branch cut as log().

cmath.sqrt(x)

Return the square root of x. This has the same branch cut as log().

Trigonometric functions

cmath.acos(x)

Return the arc cosine of x. There are two branch cuts: One extends right from 1 along the real axis to ∞. The other extends left from -1 along the real axis to -∞.

cmath.asin(x)

Return the arc sine of x. This has the same branch cuts as acos().

cmath.atan(x)

Return the arc tangent of x. There are two branch cuts: One extends from 1j along the imaginary axis to ∞j. The other extends from -1j along the imaginary axis to -∞j.

cmath.cos(x)

Return the cosine of x.

cmath.sin(x)

Return the sine of x.

cmath.tan(x)

Return the tangent of x.

Hyperbolic functions

cmath.acosh(x)

Return the inverse hyperbolic cosine of x. There is one branch cut, extending left from 1 along the real axis to -∞.

cmath.asinh(x)

Return the inverse hyperbolic sine of x. There are two branch cuts: One extends from 1j along the imaginary axis to ∞j. The other extends from -1j along the imaginary axis to -∞j.

cmath.atanh(x)

Return the inverse hyperbolic tangent of x. There are two branch cuts: One extends from 1 along the real axis to . The other extends from -1 along the real axis to -∞.

cmath.cosh(x)

Zwraca cosinus hiperboliczny z x.

cmath.sinh(x)

Zwraca sinus hiperboliczny z x.

cmath.tanh(x)

Zwraca tangens hiperboliczny z x.

Funkcje klasyfikujące

cmath.isfinite(x)

Zwraca True jeżeli obie rzeczywista i urojona część x są skończone, i False w przeciwnym wypadku.

Added in version 3.2.

cmath.isinf(x)

Zwraca True jeżeli rzeczywista lub urojona część x jest skończona, i False w przeciwnym wypadku.

cmath.isnan(x)

Zwraca True jeżeli rzeczywista lub urojona część x jest NaN, i False w przeciwnym wypadku.

cmath.isclose(a, b, *, rel_tol=1e-09, abs_tol=0.0)

Zwraca True jeżeli wartości a i b są zbliżone do siebie i False w przeciwnym wypadku.

To czy dwie wartości są zbliżone do siebie, zależy od dostarczonej absolutnej lub relatywnej tolerancji.

rel_tol is the relative tolerance – it is the maximum allowed difference between a and b, relative to the larger absolute value of a or b. For example, to set a tolerance of 5%, pass rel_tol=0.05. The default tolerance is 1e-09, which assures that the two values are the same within about 9 decimal digits. rel_tol must be greater than zero.

abs_tol is the minimum absolute tolerance – useful for comparisons near zero. abs_tol must be at least zero.

Jeżeli nie wystąpi żaden błąd wynikiem będzie: abs(a-b) <= max(rel_tol * max(abs(a), abs(b)), abs_tol).

The IEEE 754 special values of NaN, inf, and -inf will be handled according to IEEE rules. Specifically, NaN is not considered close to any other value, including NaN. inf and -inf are only considered close to themselves.

Added in version 3.5.

Zobacz także

PEP 485 – A function for testing approximate equality

Stały

cmath.pi

Stałą matematyczną π, jako liczbę zmiennoprzecinkową

cmath.e

Stałą matematyczną e, jako liczbę zmiennoprzecinkową

cmath.tau

Stałą matematyczną τ, jako liczbę zmiennoprzecinkową

Added in version 3.6.

cmath.inf

Floating-point positive infinity. Equivalent to float('inf').

Added in version 3.6.

cmath.infj

Complex number with zero real part and positive infinity imaginary part. Equivalent to complex(0.0, float('inf')).

Added in version 3.6.

cmath.nan

A floating-point „not a number” (NaN) value. Equivalent to float('nan').

Added in version 3.6.

cmath.nanj

Complex number with zero real part and NaN imaginary part. Equivalent to complex(0.0, float('nan')).

Added in version 3.6.

Note that the selection of functions is similar, but not identical, to that in module math. The reason for having two modules is that some users aren’t interested in complex numbers, and perhaps don’t even know what they are. They would rather have math.sqrt(-1) raise an exception than return a complex number. Also note that the functions defined in cmath always return a complex number, even if the answer can be expressed as a real number (in which case the complex number has an imaginary part of zero).

A note on branch cuts: They are curves along which the given function fails to be continuous. They are a necessary feature of many complex functions. It is assumed that if you need to compute with complex functions, you will understand about branch cuts. Consult almost any (not too elementary) book on complex variables for enlightenment. For information of the proper choice of branch cuts for numerical purposes, a good reference should be the following:

Zobacz także

Kahan, W: Branch cuts for complex elementary functions; or, Much ado about nothing’s sign bit. In Iserles, A., and Powell, M. (eds.), The state of the art in numerical analysis. Clarendon Press (1987) pp165–211.