Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 8 VECTORS Review 1. The length of the line represents the magnitude and the arrow indicates the direction. 2. The magnitude and direction of.

Published byGwenda Holmes Modified over 8 years ago

Similar presentations

Presentation on theme: "Chapter 8 VECTORS Review 1. The length of the line represents the magnitude and the arrow indicates the direction. 2. The magnitude and direction of."— Presentation transcript:

1

2 Chapter 8 VECTORS Review

3 1. The length of the line represents the magnitude and the arrow indicates the direction. 2. The magnitude and direction of the vector is clearly labeled.

4 A vector is a quantity that has both magnitude and direction. It is represented by an arrow. The length of the vector represents the magnitude and the arrow indicates the direction of the vector. Two vectors are equal if they have the same direction and magnitude (length). Blue and orange vectors have same magnitude but different direction. Blue and green vectors have same direction but different magnitude. Blue and purple vectors have same magnitude and direction so they are equal.

5 P Q Initial Point Terminal Point magnitude is the length direction is this angle How can we find the magnitude if we have the initial point and the terminal point? The distance formula How can we find the direction? (Is this all looking familiar for each application? You can make a right triangle and use trig to get the angle!)

6 The speed of an airplane relative to the ground is affected by wind. (actual speed w/respect to the ground If we know the speed and direction of the plane and the speed and direction of the wind, we can calculate the resulting speed and direction of the airplane.

7 AB C

8

9 Q Terminal Point direction is this angle Although it is possible to do this for any initial and terminal points, since vectors are equal as long as the direction and magnitude are the same, it is easiest to find a vector with initial point at the origin and terminal point (x, y). If we subtract the initial point from the terminal point, we will have an equivalent vector with initial point at the origin. P Initial Point A vector whose initial point is the origin is called a position vector

10 To add vectors, we put the initial point of the second vector on the terminal point of the first vector. The resultant vector has an initial point at the initial point of the first vector and a terminal point at the terminal point of the second vector (see below--better shown than put in words). Initial point of v Move w over keeping the magnitude and direction the same. To add vectors, we put the initial point of the second vector on the terminal point of the first vector. The resultant vector has an initial point at the initial point of the first vector and a terminal point at the terminal point of the second vector (see below--better shown than put in words). Terminal point of w

11 The negative of a vector is just a vector going the opposite way. A number multiplied in front of a vector is called a scalar. It means to take the vector and add together that many times.

12 Using the vectors shown, find the following:

13

14

15

16

17 0o0o N 180 o 270 o An airplane is flying 200mph at 50 o N of E. Wind velocity is 50 mph due S. What is the velocity of the plane? Scale: 50 mph = 1 inch

18 E N W S An airplane is flying 200mph at 50 o N of E. Wind velocity is 50 mph due S. What is the velocity of the plane? Scale: 50 mph = 1 inch

19 E N W S An airplane is flying 200mph at 50 o N of E. Wind velocity is 50 mph due S. What is the velocity of the plane? Scale: 50 mph = 1 inch 200 mph 50 mph V R = 165 mph @ 40° N of E

20 Use a metric ruler and protractor to find each sum or difference. Then find the magnitude and amplitude of each resultant. Magnitude = 2 cm Amplitude = 60° Magnitude = 3 cm Amplitude = 140° Magnitude = 1 cm Amplitude = 310° 1.)2.) 60° 140° 2 cm 3 cm 3.9 cm 140° 130° 3 cm 1 cm 4 cm 110° 139°

21 Use a metric ruler and protractor to find each sum or difference. Then find the magnitude and amplitude of each resultant. Magnitude = 2 cm Amplitude = 60° Magnitude = 3 cm Amplitude = 140° Magnitude = 1 cm Amplitude = 310° 1.)2.) 60° 140° 2 cm 3 cm 5.5 cm 140° 310° 3 cm 1 cm 0.6 cm 93° 217° 2 cm

22 FIND THE MAGNITUDE OF THE VERTICAL AND HORIZONTAL COMPONENTS OF EACH VECTOR. Magnitude = 2 cm Amplitude = 60° Magnitude = 3 cm Amplitude = 140° Magnitude = 1 cm Amplitude = 310° xx x y y y y = 1.7 cm x = 1 cm y = 1.9 cm x = -2.3 cm y = -0.7 cm x = 0.6 cm

23

24 Vectors are denoted with bold letters (a, b) This is the notation for a position vector. This means the point (a, b) is the terminal point and the initial point is the origin. We use vectors that are only 1 unit long to build position vectors. i is a vector 1 unit long in the x direction and j is a vector 1 unit long in the y direction. (3, 2) UNIT VECTORS

25 If we want to add vectors that are in the form ai + bj, we can just add the i components and then the j components. Let's look at this geometrically: When we want to know the magnitude of the vector (remember this is the length) we denote it Can you see from this picture how to find the length of v?

26 A unit vector is a vector with magnitude 1. If we want to find the unit vector having the same direction as a given vector, we find the magnitude of the vector and divide the vector by that value. If we want to find the unit vector having the same direction as w we need to divide w by 5. Let's check this to see if it really is 1 unit long.

27 FIND THE ORDERD PAIR THAT REPRESENTS THE VECTOR “A” TO “B”. THEN FIND THE MAGNITUDE OF “AB” 1.) A(2, 4), B(-1, 3)2.) A(4, -2), B(5, -5) 3.) A(-3, -6), B(8, -1)

28 FIND THE SUM OR DIFFERENCE OF THE GIVEN VECTORS ALGEBRAICALLY. EXPRESS THE RESULT AS AN ORDERED PAIR. 1.) 2.) (2, 6) (4, -5)

29 FIND AN ORDERED PAIR TO REPRESENT VECTOR “U” IF: 1.)2.) 3.) 4.)5.) 6.) (-1, 4) (5, -6)(6, -3) (-7, 7)(-5, 13)(-19, 27)

Download ppt "Chapter 8 VECTORS Review 1. The length of the line represents the magnitude and the arrow indicates the direction. 2. The magnitude and direction of."

Similar presentations

10.2 Vectors and Vector Value Functions

10.2 Vectors and Vector Value Functions
Vectors Lesson 4.3.

Vectors Lesson 4.3.
Vectors 6001. INTRODUCTION SCALAR QUANTITIES: _______________________________________________________ VECTOR QUANTITIES: ________________________________________________________.

Vectors INTRODUCTION SCALAR QUANTITIES: _______________________________________________________ VECTOR QUANTITIES: ________________________________________________________.
8-7 Vectors You used trigonometry to find side lengths and angle measures of right triangles. Perform vector operations geometrically. Perform vector operations.

8-7 Vectors You used trigonometry to find side lengths and angle measures of right triangles. Perform vector operations geometrically. Perform vector operations.
VECTORS.

VECTORS.
8-7 Vectors You used trigonometry to find side lengths and angle measures of right triangles. Perform vector operations geometrically. Perform vector operations.

8-7 Vectors You used trigonometry to find side lengths and angle measures of right triangles. Perform vector operations geometrically. Perform vector operations.
6.3 Vectors Copyright © by Houghton Mifflin Company, Inc. All rights reserved. 1 Students will: Represent vectors as directed line segments. Write the.

6.3 Vectors Copyright © by Houghton Mifflin Company, Inc. All rights reserved. 1 Students will: Represent vectors as directed line segments. Write the.
VECTORS AND THE GEOMETRY OF SPACE 12. 12.2 Vectors VECTORS AND THE GEOMETRY OF SPACE In this section, we will learn about: Vectors and their applications.

VECTORS AND THE GEOMETRY OF SPACE Vectors VECTORS AND THE GEOMETRY OF SPACE In this section, we will learn about: Vectors and their applications.
Copyright © Cengage Learning. All rights reserved.

Copyright © Cengage Learning. All rights reserved.
Copyright © Cengage Learning. All rights reserved.

Copyright © Cengage Learning. All rights reserved.
APPLICATIONS OF TRIGONOMETRY

APPLICATIONS OF TRIGONOMETRY
VECTORS. A vector is a quantity that has both magnitude and direction. It is represented by an arrow. The length of the vector represents the magnitude.

VECTORS. A vector is a quantity that has both magnitude and direction. It is represented by an arrow. The length of the vector represents the magnitude.
Review Displacement Average Velocity Average Acceleration

Review Displacement Average Velocity Average Acceleration
8-6 Vectors Warm Up Lesson Presentation Lesson Quiz Holt Geometry.

8-6 Vectors Warm Up Lesson Presentation Lesson Quiz Holt Geometry.
Vectors. A line segment to which a direction has been assigned is called a directed line segment. The figure below shows a directed line segment form.

Vectors. A line segment to which a direction has been assigned is called a directed line segment. The figure below shows a directed line segment form.
6.1 – Vectors in the Plane. What are Vectors? Vectors are a quantity that have both magnitude (length) and direction, usually represented with an arrow:

6.1 – Vectors in the Plane. What are Vectors? Vectors are a quantity that have both magnitude (length) and direction, usually represented with an arrow:
Chapter 6 Additional Topics in Trigonometry

Chapter 6 Additional Topics in Trigonometry
3.1 Introduction to Vectors.  Vectors indicate direction; scalars do not  Examples of scalars: time, speed, volume, temperature  Examples of vectors:

3.1 Introduction to Vectors.  Vectors indicate direction; scalars do not  Examples of scalars: time, speed, volume, temperature  Examples of vectors:
Forces in 2D Chapter 5. 5.1 Vectors Both magnitude (size) and direction Magnitude always positive Can’t have a negative speed But can have a negative.

Forces in 2D Chapter Vectors Both magnitude (size) and direction Magnitude always positive Can’t have a negative speed But can have a negative.
Vectors and the Geometry of Space 9. Vectors 9.2.

Vectors and the Geometry of Space 9. Vectors 9.2.

Similar presentations

Ads by Google