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Copyright © Cengage Learning. All rights reserved. 6.5 Trigonometric Form of a Complex Number.

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1 Copyright © Cengage Learning. All rights reserved. 6.5 Trigonometric Form of a Complex Number

2 2 What You Should Learn Plot complex numbers in the complex plane and find absolute values of complex numbers. Write trigonometric forms of complex numbers. Multiply and divide complex numbers written in trigonometric form. Use DeMoivre’s Theorem to find powers of complex numbers.

3 3 The Complex Plane

4 4 Just as real numbers can be represented by points on the real number line, you can represent a complex number z = a + bi as the point (a, b) in a coordinate plane (the complex plane). The horizontal axis is called the real axis and the vertical axis is called the imaginary axis, as shown in Figure 6.47. Figure 6.47

5 5 The Complex Plane The absolute value of a complex number a + bi is defined as the distance between the origin (0, 0) and the point (a, b).

6 6 The Complex Plane When the complex number a + bi is a real number (that is, when b = 0), this definition agrees with that given for the absolute value of a real number |a + 0i| = = |a|.

7 7 Example 1 – Finding the Absolute Value of a Complex Number Plot z = –2 + 5i and find its absolute value. Solution: The complex number z = –2 + 5i is plotted in Figure 6.48. The absolute value of z is |z| = = Figure 6.48

8 8 Trigonometric Form of a Complex Number

9 9 To work effectively with powers and roots of complex numbers, it is helpful to write complex numbers in trigonometric form. In Figure 6.49, consider the nonzero complex number a + bi. Figure 6.49

10 10 Trigonometric Form of a Complex Number By letting  be the angle from the positive real axis (measured counterclockwise) to the line segment connecting the origin and the point (a, b) you can write a = r cos  and b = r sin  where r = Consequently, you have a + bi = (r cos  ) + (r sin  )i from which you can obtain the trigonometric form of a complex number.

11 11 Trigonometric Form of a Complex Number

12 12 Example 2 – Writing a Complex Number in Trigonometric Form Write the complex number z = –2i in trigonometric form. Solution: The absolute value of z is r = | –2i | = 2.

13 13 Example 2 – Solution With a = 0, you cannot use tan  = b/a to find . Because z = –2i lies on the negative imaginary axis (see Figure 6.50), choose  = 3  /2. So, the trigonometric form is z = r (cos  + i sin  ) Figure 6.50 cont’d

14 14 Example 4 – Writing a Complex Number in Standard Form Write the complex number in standard form a + bi. Solution: Because cos (–  /3) = and sin (–  /3) = –, you can write z =

15 15 Example 4 – Solution cont’d

16 16 Multiplication and Division of Complex Numbers

17 17 Multiplication and Division of Complex Numbers The trigonometric form adapts nicely to multiplication and division of complex numbers. Suppose you are given two complex numbers z 1 = r 1 (cos  1 + i sin  1 ) and z 2 = r 2 (cos  2 + i sin  2 )

18 18 Multiplication and Division of Complex Numbers The product of z 1 and z 2 is z 1 z 2 = r 1 r 2 (cos  1 + i sin  1 )(cos  2 + i sin  2 ) = r 1 r 2 [(cos  1 cos  2 – sin  1 sin  2 ) + i(sin  1 cos  2 + cos  1 sin  2 )] = r 1 r 2 [(cos (  1 +  2 ) + i sin(  1 +  2 )]. Sum and difference formulas

19 19 Multiplication and Division of Complex Numbers

20 20 Example 5 – Multiplying Complex Numbers in Trigonometric Form Find the product z 1 z 2 of the complex numbers. Solution:

21 21 Example 5 – Solution = 6(cos  + i sin  ) = 6[–1 + i (0)] = –6 The numbers z 1,z 2 and z 1 z 2 are plotted in Figure 6.52. cont’d Figure 6.52

22 22 Powers of Complex Numbers

23 23 Powers of Complex Numbers The trigonometric form of a complex number is used to raise a complex number to a power. To accomplish this, consider repeated use of the multiplication rule. Read this slide and the next, but do not copy. z = r (cos  + i sin  ) z 2 = r (cos  + i sin  ) r (cos  + i sin  ) = r 2 (cos 2  + i sin 2  ) z 3 = r 2 (cos 2  + i sin 2  ) r (cos  + i sin  ) = r 3 (cos 3  + i sin 3  )

24 24 Powers of Complex Numbers z 4 = r 4 (cos 4  + i sin 4  ) z 5 = r 5 (cos 5  + i sin 5  ). This pattern leads to DeMoivre’s Theorem, which is named after the French mathematician Abraham DeMoivre (1667–1754).

25 25 Powers of Complex Numbers

26 26 Example 8 – Finding a Power of a Complex Number Use DeMoivre’s Theorem to find Solution: First convert the complex number to trigonometric form using previous formulas for r and theta: r = = 2 and  = arctan

27 27 Example 8 – Solution So, the trigonometric form is Then, by DeMoivre’s Theorem, you have (1 + i) 12 cont’d

28 28 Example 8 – Solution = 4096(cos 4  + i sin 4  ) = 4096(1 + 0) = 4096. cont’d

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