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1 Copyright © Cengage Learning. All rights reserved. 1 Equations, Inequalities, and Mathematical Modeling.

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1 1 Copyright © Cengage Learning. All rights reserved. 1 Equations, Inequalities, and Mathematical Modeling

2 1.5 COMPLEX NUMBERS Copyright © Cengage Learning. All rights reserved.

3 3 Use the imaginary unit i to write complex numbers. Add, subtract, and multiply complex numbers. Use complex conjugates to write the quotient of two complex numbers in standard form. Find complex solutions of quadratic equations. What You Should Learn

4 4 The Imaginary Unit i

5 5 We have learned that some quadratic equations have no real solutions. For instance, the quadratic equation x 2 + 1 = 0 has no real solution because there is no real number x that can be squared to produce –1. To overcome this deficiency, mathematicians created an expanded system of numbers using the imaginary unit i, defined as i = where i 2 = –1. Imaginary unit

6 6 The Imaginary Unit i By adding real numbers to real multiples of this imaginary unit, the set of complex numbers is obtained. Each complex number can be written in the standard form a + bi. For instance, the standard form of the complex number –5 + is –5 + 3i because

7 7 The Imaginary Unit i In the standard form a + bi, the real number a is called the real part of the complex number a + bi, and the number bi (where b is a real number) is called the imaginary part of the complex number.

8 8 The Imaginary Unit i The set of real numbers is a subset of the set of complex numbers, as shown in Figure 1.23. This is true because every real number a can be written as a complex number using b = 0. That is, for every real number a, you can write a = a + 0i. Figure 1.23

9 9 The Imaginary Unit i

10 10 Operations with Complex Numbers

11 11 Operations with Complex Numbers To add (or subtract) two complex numbers, you add (or subtract) the real and imaginary parts of the numbers separately.

12 12 Operations with Complex Numbers The additive identity in the complex number system is zero (the same as in the real number system). Furthermore, the additive inverse of the complex number a + bi is –(a + bi) = –a – bi. So, you have (a + bi) + (–a – bi) = 0 + 0i = 0. Additive inverse

13 13 Example 1 – Adding and Subtracting Complex Numbers a. (4 + 7i) + (1 – 6i) = 4 + 7i + 1 – 6i = (4 + 1) + (7i – 6i) = 5 + i b. (1 + 2i) – (4 + 2i) = 1 + 2i – 4 – 2i = (1 – 4) + (2i – 2i) = –3 + 0 = –3 Remove parentheses. Group like terms. Write in standard form. Remove parentheses. Group like terms. Simplify. Write in standard form.

14 14 Example 1 – Adding and Subtracting Complex Numbers c. 3i – (–2 + 3i) – (2 + 5i) = 3i + 2 – 3i – 2 – 5i = (2 – 2) + (3i – 3i – 5i) = 0 – 5i = – 5i d. (3 + 2i) + (4 – i) – (7 + i) = 3 + 2i + 4 – i – 7 – i = (3 + 4 – 7) + (2i – i – i) = 0 + 0i = 0 cont’d

15 15 Operations with Complex Numbers Note in Examples 1(b) and 1(d) that the sum of two complex numbers can be a real number. Many of the properties of real numbers are valid for complex numbers as well. Here are some examples. Associative Properties of Addition and Multiplication Commutative Properties of Addition and Multiplication Distributive Property of Multiplication Over Addition

16 16 Operations with Complex Numbers Notice below how these properties are used when two complex numbers are multiplied. (a + bi)(c + di) = a(c + di) + bi(c + di) = ac + (ad)i + (bc)i + (bd)i 2 = ac + (ad)i + (bc)i + (bd)(–1) = ac – bd + (ad)i + (bc)i = (ac – bd) + (ad + bc)i Rather than trying to memorize this multiplication rule, you should simply remember how the Distributive Property is used to multiply two complex numbers. Distributive Property i 2 = –1 Commutative Property Associative Property

17 17 Example 2 – Multiplying Complex Numbers a. 4(–2 + 3i) = 4(–2) + 4(3i) = – 8 + 12i b. (2 – i)(4 + 3i) = 2(4 + 3i) – i(4 + 3i) = 8 + 6i – 4i – 3i 2 = 8 + 6i – 4i – 3(–1) = (8 + 3) +(6i – 4i) = 11 + 2i Group like terms. Simplify. Write in standard form. Distributive Property i 2 = –1

18 18 Example 2 – Multiplying Complex Numbers c. (3 + 2i)(3 – 2i) = 3(3 – 2i) + 2i(3 – 2i) = 9 – 6i + 6i – 4i 2 = 9 – 6i + 6i – 4(–1) = 9 + 4 = 13 Simplify. Write in standard form. Distributive Property i 2 = –1 cont’d

19 19 Example 2 – Multiplying Complex Numbers d. (3 + 2i) 2 = (3 + 2i)(3 + 2i) = 3(3 + 2i) + 2i(3 + 2i) = 9 + 6i + 6i + 4i 2 = 9 + 6i + 6i + 4(–1) = 9 + 12i – 4 = 5 + 12i Simplify. Write in standard form. Distributive Property i 2 = –1 Square of a binomial cont’d

20 20 Complex Conjugates

21 21 Complex Conjugates Notice in Example 2(c) that the product of two complex numbers can be a real number. This occurs with pairs of complex numbers of the form a + bi and a – bi, called complex conjugates. (a + bi)(a – bi) = a 2 – abi + abi – b 2 i 2 = a 2 – b 2 (–1) = a 2 + b 2

22 22 Complex Conjugates To write the quotient of a + bi and c + di in standard form, where c and d are not both zero, multiply the numerator and denominator by the complex conjugate of the denominator to obtain Standard form

23 23 Example 4 – Writing a Quotient of Complex Numbers in Standard Form Multiply numerator and denominator by complex conjugate of denominator. Expand. Simplify. Write in standard form. i 2 = –1

24 24 Complex Solutions of Quadratic Equations

25 25 Complex Solutions of Quadratic Equations When using the Quadratic Formula to solve a quadratic equation, you often obtain a result such as, which you know is not a real number. By factoring out i =, you can write this number in standard form. The number i is called the principal square root of –3.

26 26 Example 6 – Complex Solutions of a Quadratic Equation Solve (a) x 2 + 4 = 0 and (b) 3x 2 – 2x + 5 = 0. Solution: a. x 2 + 4 = 0 x 2 = –4 x =  2i b. 3x 2 – 2x + 5 = 0 Write original equation. Subtract 4 from each side. Extract square roots. Write original equation. Quadratic Formula

27 27 Example 6 – Solution Simplify. Write in standard form. cont’d


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