1 / 42

ET 201 ~ ELECTRICAL CIRCUITS COMPLEX NUMBER SYSTEM

ET 201 ~ ELECTRICAL CIRCUITS COMPLEX NUMBER SYSTEM. Define and explain complex number Rectangular form Polar form Mathematical operations. (CHAPTER 2). COMPLEX NUMBERS. 2. Complex Numbers.

llangton
Download Presentation

ET 201 ~ ELECTRICAL CIRCUITS COMPLEX NUMBER SYSTEM

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. ET 201 ~ ELECTRICAL CIRCUITSCOMPLEX NUMBER SYSTEM Define and explaincomplex number Rectangular form Polar form Mathematical operations (CHAPTER 2)

  2. COMPLEXNUMBERS

  3. 2. Complex Numbers • A complex number represents a point in a two-dimensional plane located with reference to two distinct axes. • This point can also determine a radius vector drawn from the origin to the point. • The horizontal axis is called the real axis, while the vertical axis is called the imaginary ( j )axis.

  4. 2.1 Rectangular Form • The format for the rectangular form is • The letter C was chosen from the word complex • The bold face (C) notation is for any number with magnitude and direction. • The italic notation is for magnitude only.

  5. 2.1 Rectangular Form Example 14.13(a) Sketch the complex number C = 3 + j4 in the complex plane Solution

  6. 2.1 Rectangular Form Example 14.13(b) Sketch the complex number C = 0 – j6 in the complex plane Solution

  7. 2.1 Rectangular Form Example 14.13(c) Sketch the complex number C = -10 – j20 in the complex plane Solution

  8. 2.2 Polar Form • The format for the polar form is • Where: • Z : magnitude only • q : angle measured counterclockwise (CCW) from the positive real axis. • Angles measured in the clockwise direction from the positive real axis must have a negative sign associated with them.

  9. 2.2 Polar Form

  10. 2.2 Polar Form Example 14.14(a) Counterclockwise (CCW)

  11. 2.2 Polar Form Example 14.14(b) Clockwise (CW)

  12. 2.2 Polar Form Example 14.14(c)

  13. 14.9 Conversion Between Forms • 1. Rectangular to Polar

  14. 14.9 Conversion Between Forms • 2. Polar to Rectangular

  15. 2.3 Conversion Between Forms Example 14.15 Convert C = 4 + j4 to polar form Solution

  16. 2.3 Conversion Between Forms Example 14.16 Convert C = 1045 to rectangular form Solution

  17. 2.3 Conversion Between Forms Example 14.17 Convert C = - 6 + j3 to polar form Solution

  18. 2.3 Conversion Between Forms Example 14.18 Convert C = 10  230 to rectangular form Solution

  19. 2.4 Mathematical Operations with Complex Numbers • Complex numbers lend themselves readily to the basic mathematical operations of addition, subtraction, multiplication, and division. • A few basic rules and definitions must be understood before considering these operations:

  20. 2.4 Mathematical Operations with Complex Numbers Complex Conjugate • The conjugate or complex conjugate of a complex number can be found by simply changing the sign of the imaginary part in the rectangular form or by using the negative of the angle of the polar form

  21. 2.4 Mathematical Operations with Complex Numbers Complex Conjugate In rectangular form, the conjugate of: C = 2 + j3 is 2 – j3

  22. 2.4 Mathematical Operations with Complex Numbers Complex Conjugate In polar form, the conjugate of: • C = 2  30o • is 2 30o

  23. 2.4 Mathematical Operations with Complex Numbers Reciprocal • The reciprocal of a complex number is 1 divided by the complex number. • In rectangular form, the reciprocal of: • In polar form, the reciprocal of: is is

  24. 2.4 Mathematical Operations with Complex Numbers Addition • To add two or more complex numbers, simply add the real and imaginary parts separately.

  25. 2.4 Mathematical Operations with Complex Numbers Example 14.19(a) Find C1 + C2. Solution

  26. 2.4 Mathematical Operations with Complex Numbers Example 14.19(b) Find C1 + C2 Solution

  27. 2.4 Mathematical Operations with Complex Numbers Subtraction • In subtraction, the real and imaginary parts are again considered separately . NOTE Addition or subtraction cannot be performed in polar form unless the complex numbers have the same angle ө or unless they differ only by multiples of 180°

  28. 2.4 Mathematical Operations with Complex Numbers Example 14.20(a) Find C1 - C2 Solution

  29. 2.4 Mathematical Operations with Complex Numbers Example 14.20(b) Find C1 - C2 Solution

  30. 2.4 Mathematical Operations with Complex Numbers Example 14.21(a) NOTE Addition or subtraction cannot be performed in polar form unless the complex numbers have the same angle ө or unless they differ only by multiples of 180°

  31. 2.4 Mathematical Operations with Complex Numbers Example 14.21(b) NOTE Addition or subtraction cannot be performed in polar form unless the complex numbers have the same angle ө or unless they differ only by multiples of 180°

  32. 2.4 Mathematical Operations with Complex Numbers Multiplication • To multiply two complex numbers in rectangular form, multiply the real and imaginary parts of one in turn by the real and imaginary parts of the other. • In rectangular form: • In polar form:

  33. 2.4 Mathematical Operations with Complex Numbers Example 14.22(a) Find C1C2. Solution

  34. 2.4 Mathematical Operations with Complex Numbers Example 14.22(b) Find C1C2. Solution

  35. 2.4 Mathematical Operations with Complex Numbers Example 14.23(a) Find C1C2. Solution

  36. 14.10 Mathematical Operations with Complex Numbers Example 14.23(b) Find C1C2. Solution

  37. 14.10 Mathematical Operations with Complex Numbers Division • To divide two complex numbers in rectangular form, multiply the numerator and denominator by the conjugate of the denominator and the resulting real and imaginary parts collected. • In rectangular form: • In polar form:

  38. 2.4 Mathematical Operations with Complex Numbers Example 14.24(a) Find Solution

  39. 2.4 Mathematical Operations with Complex Numbers Example 14.24(b) Find Solution

  40. 2.4 Mathematical Operations with Complex Numbers Example 14.25(a) Find Solution

  41. 2.4 Mathematical Operations with Complex Numbers Example 14.25(b) Find Solution

  42. 2.4 Mathematical Operations with Complex Numbers • Addition • Subtraction • Multiplication • Division • Reciprocal • Complex conjugate • Euler’s identity

More Related