Presentation is loading. Please wait.

Presentation is loading. Please wait.

Roots of Complex Numbers

Published byKatrina Small Modified over 5 years ago

Similar presentations

Presentation on theme: "Roots of Complex Numbers"— Presentation transcript:

1 Roots of Complex Numbers
Sec. 6.6c

2 From last class: The complex number The complex number
is a third root of –8 is an eighth root of 1

3 Definition v = z n A complex number v = a + bi is an nth root of z if
If z = 1, then v is an nth root of unity.

4 Finding nth Roots of a Complex Number
If , then the n distinct complex numbers where k = 0, 1, 2,…, n – 1, are the nth roots of the complex number z.

5 Let’s see this in practice:
Find the fourth roots of Use the new formula, with r = 5, n = 4, k = 0 – 3, k = 0:

6 Let’s see this in practice:
Find the fourth roots of Use the new formula, with r = 5, n = 4, k = 0 – 3, k = 1:

7 Let’s see this in practice:
Find the fourth roots of Use the new formula, with r = 5, n = 4, k = 0 – 3, k = 2:

8 Let’s see this in practice:
Find the fourth roots of Use the new formula, with r = 5, n = 4, k = 0 – 3, k = 3: How would we verify these algebraically???

9 Let’s see this in practice:
Find the cube roots of –1 and plot them. First, rewrite the complex number in trig. form: Use the new formula, with r = 1, n = 3, k = 0 – 2,

10 Let’s see this in practice:
Find the cube roots of –1 and plot them. First, rewrite the complex number in trig. form: Use the new formula, with r = 1, n = 3, k = 0 – 2,

11 Let’s see this in practice:
Find the cube roots of –1 and plot them. First, rewrite the complex number in trig. form: Use the new formula, with r = 1, n = 3, k = 0 – 2,

12 Let’s see this in practice:
Find the cube roots of –1 and plot them. First, rewrite the complex number in trig. form: Use the new formula, with r = 1, n = 3, k = 0 – 2, The cube roots of –1 Now, how do we sketch the graph???

Download ppt "Roots of Complex Numbers"

Similar presentations

Complex Numbers in Polar Form; DeMoivre’s Theorem 6.5

Complex Numbers in Polar Form; DeMoivre’s Theorem 6.5
2-3 Geometric Sequences Definitions & Equations

2-3 Geometric Sequences Definitions & Equations
10.6 Roots of Complex Numbers. Notice these numerical statements. These are true! But I would like to write them a bit differently. 32 = 2 5 –125 = (–5)

10.6 Roots of Complex Numbers. Notice these numerical statements. These are true! But I would like to write them a bit differently. 32 = 2 5 –125 = (–5)
Precalculus Mr. Ueland 2 nd Period Rm 156. Today in PreCalculus Announcements/Prayer New material: Sec 2.5b, “Complex Numbers” Continue working on Assignment.

Precalculus Mr. Ueland 2 nd Period Rm 156. Today in PreCalculus Announcements/Prayer New material: Sec 2.5b, “Complex Numbers” Continue working on Assignment.
Complex Numbers in Polar Form; DeMoivre’s Theorem

Complex Numbers in Polar Form; DeMoivre’s Theorem
6.5 Trig. Form of a Complex Number Ex. Z = -2 + 5i -2 5.

6.5 Trig. Form of a Complex Number Ex. Z = i -2 5.
Copyright © 2011 Pearson, Inc. 6.6 De Moivre’s Theorem and nth Roots.

Copyright © 2011 Pearson, Inc. 6.6 De Moivre’s Theorem and nth Roots.
Sec. 6.6b. One reason for writing complex numbers in trigonometric form is the convenience for multiplying and dividing: T The product i i i involves.

Sec. 6.6b. One reason for writing complex numbers in trigonometric form is the convenience for multiplying and dividing: T The product i i i involves.
DeMoivre’s Theorem The Complex Plane. Complex Number A complex number z = x + yi can be interpreted geometrically as the point (x, y) in the complex plane.

DeMoivre’s Theorem The Complex Plane. Complex Number A complex number z = x + yi can be interpreted geometrically as the point (x, y) in the complex plane.
Section 4.2 Rational Exponents.

Section 4.2 Rational Exponents.
Roots of Complex Numbers Sec. 6.6c HW: p. 558 39-59 odd.

Roots of Complex Numbers Sec. 6.6c HW: p odd.
GEOMETRIC SEQUENCES These are sequences where the ratio of successive terms of a sequence is always the same number. This number is called the common.

GEOMETRIC SEQUENCES These are sequences where the ratio of successive terms of a sequence is always the same number. This number is called the common.
Section 6.5 Complex Numbers in Polar Form. Overview Recall that a complex number is written in the form a + bi, where a and b are real numbers and While.

Section 6.5 Complex Numbers in Polar Form. Overview Recall that a complex number is written in the form a + bi, where a and b are real numbers and While.
Section 8.1 Complex Numbers.

Section 8.1 Complex Numbers.
Linear Factorizations Sec. 2.6b. First, remind me of the definition of a linear factorization… f (x) = a(x – z )(x – z )…(x – z ) An equation in the following.

Linear Factorizations Sec. 2.6b. First, remind me of the definition of a linear factorization… f (x) = a(x – z )(x – z )…(x – z ) An equation in the following.
2.3 Real and Non Real Roots of a Polynomial Polynomial Identities Secondary Math 3.

2.3 Real and Non Real Roots of a Polynomial Polynomial Identities Secondary Math 3.
The Complex Plane; De Moivre’s Theorem. Polar Form.

The Complex Plane; De Moivre’s Theorem. Polar Form.
Lesson 78 – Polar Form of Complex Numbers HL2 Math - Santowski 11/16/15.

Lesson 78 – Polar Form of Complex Numbers HL2 Math - Santowski 11/16/15.
Copyright © 2009 Pearson Addison-Wesley1.1-1 8.6-1 De Moivre’s Theorem; Powers and Roots of Complex Numbers 8.4 Powers of Complex Numbers (De Moivre’s.

Copyright © 2009 Pearson Addison-Wesley De Moivre’s Theorem; Powers and Roots of Complex Numbers 8.4 Powers of Complex Numbers (De Moivre’s.
Algebra 2 Lesson 7-1 (Page 363) ALGEBRA 2 LESSON 7-1 Roots and Radical Expressions 7-1.

Algebra 2 Lesson 7-1 (Page 363) ALGEBRA 2 LESSON 7-1 Roots and Radical Expressions 7-1.

Similar presentations

Ads by Google