## Hot answers tagged complex-numbers

38

In python, you can put ‘j’ or ‘J’ after a number to make it imaginary, so you can write complex literals easily:
>>> 1j
1j
>>> 1J
1j
>>> 1j * 1j
(-1+0j)
The ‘j’ suffix comes from electrical engineering, where the variable ‘i’ is usually used for current. (Reasoning found here.)
The type of a complex number is complex, and you ...

37

This turned out to be a bit verbose, but I hope it fully answers your question...
A Gaussian integer is a complex number of the form
G = a+bi
where i2 = -1, and a and b are integers.
The Gaussian integers form a unique factorization domain. Some of them act as units (e.g. 1, -1, i, and -i), some as primes (e.g. 1 + i), and the rest composite, that can be ...

33

printf("%f + i%f\n", creal(result), cimag(result));
I don't believe there's a specific format specifier for the C99 complex type.

29

Complex types are in the C language since C99 standard (-std=c99 option of GCC). Some compilers may implement complex types even in more earlier modes, but this is non-standard and non-portable extension (e.g. IBM XL, GCC, may be intel,... ).
You can start from http://en.wikipedia.org/wiki/Complex.h - it gives a description of functions from complex.h
This ...

28

What's wrong with just separating it out into real and imaginary parts? scipy.integrate.quad requires the integrated function return floats (aka real numbers) for the algorithm it uses.
import scipy
from scipy.integrate import quad
def complex_quadrature(func, a, b, **kwargs):
def real_func(x):
return scipy.real(func(x))
def imag_func(x):
...

26

You can't properly implement many of the std::complex operations on integers. E.g.,
template <class T>
T abs(const complex<T> &z);
for a complex<long> cannot have T = long return value when complex numbers are represented as (real,imag) pairs, since it returns the value of sqrt(pow(z.real(), 2) + pow(z.imag(), 2)). Only a few of the ...

25

This seems to do what you want:
numpy.apply_along_axis(lambda args: [complex(*args)], 3, Data)
Here is another solution:
numpy.vectorize(complex)(Data[...,0], Data[...,1]) # The ellipsis is equivalent here to ":,:,:"
And yet another simpler solution:
Data[...,0] + 1j * Data[...,1]
PS: If you want to save memory (no intermediate array):
result = ...

23

I guess this blog entry is one good explanation:
The key word is rotation (as opposed to direction for negative numbers, which are as stranger as imaginary number when you think of them: less than nothing ?)
Like negative numbers modeling flipping, imaginary numbers can model anything that rotates between two dimensions “X” and “Y”. Or anything with a ...

23

According to the C++ ISO spec, §26.2/2:
The effect of instantiating the template complex for any type other than float, double or long double is unspecified.
In other words, the compiler can do whatever it wants to when you instantiate complex<int>. The fact that you're getting 0 here is perfectly well-defined behavior from a language ...

21

Problem: not only am I a programmer, I am a mathematician.
Solution: plow ahead anyway.
There's nothing really magical to complex numbers. The idea behind their inception is that there's something wrong with real numbers. If you've got an equation x^2 + 4, this is never zero, whereas x^2 - 2 is zero twice. So mathematicians got really angry and wanted there ...

16

The simplest way I can find to work around this issue is to simply switch the order of multiplication.
If in testcplx.pyx I change
varc128 = varc128 * varf64
to
varc128 = varf64 * varc128
I change from the failing situation to described to one that works correctly. This scenario is useful as it allows a direct diff of the produced C code.
tl;dr
The ...

15

Here's my attempt. I winged the color function a bit.
ParametricPlot[
(*just need a vis function that will allow x and y to be in the color function*)
{x, y}, {x, -6, 3}, {y, -3, 3},
(*color and mesh functions don't trigger refinement, so just use a big grid*)
PlotPoints -> 50, MaxRecursion -> 0, Mesh -> 50,
(*turn off scaling so we can do ...

15

There's of course the rather obvious:
Data[...,0] + 1j * Data[...,1]

14

This works:
#include <complex>
#include <iostream>
int main()
{
std::complex<double> z(0,2);
double n = 3.0; // Note, double
std::cout << z * n << std::endl;
}
Because complex is composed of doubles, it multiplies with doubles. Looking at the declaration:
template <typename T>
inline complex<T> ...

14

In C99, there is a complex type. Include complex.h; you may need to link with -lm on gcc. Note that Microsoft Visual C does not support complex; if you need to use this compiler, maybe you can sprinkle in some C++ and use the complex template.
I is defined as the imaginary unit, and cexp does exponentiation. Full code example:
#include <complex.h>
...

13

Here's my variation on the function given by Axel Boldt who was inspired by Jan Homann. Both of the linked to pages have some nice graphics.
ComplexGraph[f_, {xmin_, xmax_}, {ymin_, ymax_}, opts:OptionsPattern[]] :=
RegionPlot[True, {x, xmin, xmax}, {y, ymin, ymax}, opts,
PlotPoints -> 100, ColorFunctionScaling -> False,
ColorFunction -> ...

13

I wrote the following:
https://github.com/dankogai/swift-complex
Just add complex.swift to your project and you can go like:
let z = 1-1.i
It has all functions and operators that of C++11 covers.
Unlike C++11 complex.swift is not generic -- z.real and z.imag are always Double.
But the necessity for complex integer is very moot and IMHO it should be ...

12

You are interested in two numbers : A=ac−bd and B=ad+bc.
Compute three real multiplications S1=ac,S2=bd, and S3=(a+b)(c+d).
Now you can compute the results as
A=S1−S2 and B=S3−S1−S2.
This process is called Karatsuba multiplication and used heavily in Algorithm analysis.
It is used in classical problem of finding closest pair of point.

12

[~]
|1> import numpy as np
[~]
|2> a = np.zeros(1000000, dtype=np.int16)
[~]
|3> b = a.astype(np.float32).view(np.complex64)
[~]
|4> b.shape
(500000,)
[~]
|5> b.dtype
dtype('complex64')

12

For the + operator, Python defines three "special" methods that an object may implement:
__add__: adds two items (+ operator). When you do a + b, the __add__ method of a is called with b as an argument.
__radd__: reflected add; for a + b, the __radd__ method of b is called with a as an instance. This is only used when a doesn't know how to do the add and ...

12

The arithmetic in is_arithmetic is a misnomer. Or rather, it's a C++-nomer. It doesn't mean the same thing as it means in English. It just means it's one of the built-in numeric types(int, float, etc...). std::complex is not a built-in, it is a class.
Do you really need that static_assert? Why not just let the user try it with any type? If the type ...

12

Probably for compatibility with the helper functions. For example:
template<class T> T abs (const complex<T>& x);
If T == int, abs would return int, which would mean a massive loss in precision.

11

A C++ compiler could choose to support the _Complex keyword as an extension (and a few do), but that isn't portable. If you want to have a portable C++ solution, you need to use the C++ std::complex templates, unfortunately.
The good news is that C++ std::complex numbers are guaranteed to be compatible with C99 complex numbers (in the sense that a pointer ...

11

It prints 0j to indicate that it's still a complex value. You can also type it back in that way:
>>> 0j
0j
The rest is probably the result of the magic of IEEE 754 floating point representation, which makes a distinction between 0 and -0, the so-called signed zero. Basically, there's a single bit that says whether the number is positive or ...

11

The behaviour of the program depends on the language standard mode of gcc:
There is a gcc extension for a built-in literal suffix i that produces C99 complex numbers. Those are distinct built-in types like _Complex double, as opposed to the "user-defined" class (template specialization) std::complex<double> used in C++.
In C++14, C++ now has a ...

10

Another, more vectorized way:
sel = a == real(a); % choose only real elements
only_reals = a( sel );

10

>>> n = 3.4+2.3j
>>> n
(3.4+2.3j)
>>> '({0.real:.2f} + {0.imag:.2f}i)'.format(n)
'(3.40 + 2.30i)'
>>> '({c.real:.2f} + {c.imag:.2f}i)'.format(c=n)
'(3.40 + 2.30i)'
To handle both positive and negative imaginary portions properly you would need a even more complicated formatting operation:
>>> n = 3.4-2.3j
...

10

If you have two objects, A and B, and you want to increment A by B, without operator+=, you would do this:
A = A + B;
This will, in normal implementations, involve the creation of a third (temporary) object, which is then copied back to A. However, with operator+=, A can be modified in place, so this is normally less work, and therefore more efficient.
...

10

Look at the decompiled Sqrt method.
public static Complex Sqrt(Complex value)
{
return Complex.FromPolarCoordinates(Math.Sqrt(value.Magnitude), value.Phase / 2.0);
}
There is in fact a rounding error caused by using polar coordinates and radians. value.Phase / 2.0 will return pi/2, which isn't an exactly representable number. When converting from ...

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