Python supports Complex Numbers and are built-in to the language. You can create complex numbers either by specifying the number in (real + imagJ) form or using a built-in method complex(a, b).

1 #!/usr/local/bin/python3.2

2 # Filename: ComplexNum.py

3

4 # How Imaginary Number Arithmetic Works.

5 print('1j + 1j :', 1j + 1j)

6 print('3j - 1j :', 3j - 1j)

7 print('2j * 1j :', 2j * 1j)

8 print('2j / 1j :', 2j / 1j)

9

10 # complex(real, imagJ)

11 print('complex(1, 1) :', complex(1, 1))

12

13 # Make Complex Numbers bit More Complex. Arithmetic on real and imagJ parts. :)

14 print('3 * complex(2, 3) :', 3 * complex(2, 3))

15 print('2j * complex(4, 6) :', 2j * complex(4, 6))

16 print('(2 + 4j) * complex(4, 2) :', (2 + 4j) * complex(4, 2))

17 print('(2 + 4j) * (4 + 2j) :', (2 + 4j) * (4 + 2j))

18 print('complex(2, 4) * complex(4, 2) :', complex(2, 4) * complex(4, 2))

You can download the file here: ComplexNum.py

1j + 1j : 2j

3j - 1j : 2j

2j * 1j : (-2+0j)

2j / 1j : (2+0j)

complex(1, 1) : (1+1j)

3 * complex(2, 3) : (6+9j)

2j * complex(4, 6) : (-12+8j)

(2 + 4j) * complex(4, 2) : 20j

(2 + 4j) * (4 + 2j) : 20j

complex(2, 4) * complex(4, 2) : 20j

**Complex Numbers:**- For Electronic Engineers python uses j or J instead of an i for imaginary numbers.
- j or J means square root of -1.
- You can perform arithmetic operations on Complex Numbers.
- Both real and imagJ part are floating-point numbers.
- Complex Number has a nonzero real part.
- cmath library. (for your reference.)

**(Post in your comments if i left out something important so i can add in here.)****How Complex Numbers Works.**1 #!/usr/local/bin/python3.2

2 # Filename: ComplexNum.py

3

4 # How Imaginary Number Arithmetic Works.

5 print('1j + 1j :', 1j + 1j)

6 print('3j - 1j :', 3j - 1j)

7 print('2j * 1j :', 2j * 1j)

8 print('2j / 1j :', 2j / 1j)

9

10 # complex(real, imagJ)

11 print('complex(1, 1) :', complex(1, 1))

12

13 # Make Complex Numbers bit More Complex. Arithmetic on real and imagJ parts. :)

14 print('3 * complex(2, 3) :', 3 * complex(2, 3))

15 print('2j * complex(4, 6) :', 2j * complex(4, 6))

16 print('(2 + 4j) * complex(4, 2) :', (2 + 4j) * complex(4, 2))

17 print('(2 + 4j) * (4 + 2j) :', (2 + 4j) * (4 + 2j))

18 print('complex(2, 4) * complex(4, 2) :', complex(2, 4) * complex(4, 2))

You can download the file here: ComplexNum.py

**Output:**1j + 1j : 2j

3j - 1j : 2j

2j * 1j : (-2+0j)

2j / 1j : (2+0j)

complex(1, 1) : (1+1j)

3 * complex(2, 3) : (6+9j)

2j * complex(4, 6) : (-12+8j)

(2 + 4j) * complex(4, 2) : 20j

(2 + 4j) * (4 + 2j) : 20j

complex(2, 4) * complex(4, 2) : 20j

**Explanation:**- Line #5 & #6 are pretty much self-explained.
- Line #7 2j * 1j = 2j^2. As we know that j here means square root of -1. Now j^2 equals -1. leads to the output of (-2 + 0j). As we know that a complex number has a nonzero real part.
- Line #8 2j / 1j = (2+0j). Complex Part division is a bit harder maybe or not. Because we need to multiply but top and bottom by what we call
**complex conjugate**. This is what you get when you change the sign of the imaginary part but not the real part. 2j/1j * -1j/-1j, i.e, -2j^2/-1j^2. Minus signs cancels out we are left with (2 + 0j). - Line #11 uses python interpreter built-in function complex(a, b). But the output has nothing much that i can explain.

**Hope this Helps! Please write your comments it will help me improve.**