Presentation is loading. Please wait.

Presentation is loading. Please wait.

Vectors Maggie Ambrose Maddy Farber. Hook… Component Form of a Vector  If v is a vector in a plane whose initial point is the origin and whose terminal.

Published byLeah Houff Modified over 10 years ago

Similar presentations

Presentation on theme: "Vectors Maggie Ambrose Maddy Farber. Hook… Component Form of a Vector  If v is a vector in a plane whose initial point is the origin and whose terminal."— Presentation transcript:

1 Vectors Maggie Ambrose Maddy Farber

2 Hook…

3 Component Form of a Vector  If v is a vector in a plane whose initial point is the origin and whose terminal point is, then the component form of is given by.  The coordinates of and are called the components of.

4 Magnitude of a Vector  The magnitude is the length of a vector.  Let   In a 3D coordinate plane, the length is found in the same way.  Let 

5 Find the component and length of the vector v that has initial point (3,-7) and terminal point (-2,5).

6 Scalar Multiple of a Vector  Let and let be a scalar.  The scalar multiple of and is the vector.  The magnitude of the scalar multiple is equal to the scalar times the magnitude of.

7 Find the scalar multiple. Let k=6 and let u=2i-j.

8 Unit Vector  If, then is a unit vector.  If is a nonzero vector in the plane, then the vector has a magnitude of 1 in the same direction as.  In a 3D coordinate plane, the unit vector is found the same way.

9 Find a unit vector in the direction of v=-2i+5j.

10 Dot Product  The dot product of and is  The dot product and is  The dot product of u and v can also be written as

11 Given u=2i-2j and v=5i+8j, find the dot product of u and v.

12 Angle Between Two Vectors  The angle between two nonzero vectors is the angle,, between their respective standard position vectors.  If theta is the angle between two nonzero vectors u and v, then

13 For u=3i-j+2k and v=-4i+2k, find the angle between u and v.

14 Orthogonal vs. Parallel  Orthogonal vectors are perpendicular.  The vectors and are orthogonal if, or if the angle between them is  The vectors and are parallel if they are scalar multiples of each other, or the angle between them is zero.

15 Given u=j+6k and v=i-2j-k, determine whether u and v are orthogonal, parallel, or neither.

16 Projection  If and are nonzero vectors, then the projection of onto is given by u v projection of u onto v

17 Find the projection of onto. Let and

18 Bibliography Larson, Roland E., Robert P. Hostetler, and Bruce H. Edwards. Calculus. 5th ed. Washington, D.C.: D.C. Heath and Company, 1994.

Download ppt "Vectors Maggie Ambrose Maddy Farber. Hook… Component Form of a Vector  If v is a vector in a plane whose initial point is the origin and whose terminal."

Similar presentations

10.2 Vectors and Vector Value Functions

10.2 Vectors and Vector Value Functions
Chapter 10 Vocabulary.

Chapter 10 Vocabulary.
Section 4.1 – Vectors (in component form)

Section 4.1 – Vectors (in component form)
Euclidean m-Space & Linear Equations Euclidean m-space.

Euclidean m-Space & Linear Equations Euclidean m-space.
11 Analytic Geometry in Three Dimensions

11 Analytic Geometry in Three Dimensions
Digital Lesson Vectors.

Digital Lesson Vectors.
10.5 The Dot Product. Theorem Properties of Dot Product If u, v, and w are vectors, then Commutative Property Distributive Property.

10.5 The Dot Product. Theorem Properties of Dot Product If u, v, and w are vectors, then Commutative Property Distributive Property.
24. Dot Product of Vectors. What you’ll learn about  How to find the Dot Product  How to find the Angle Between Vectors  Projecting One Vector onto.

24. Dot Product of Vectors. What you’ll learn about  How to find the Dot Product  How to find the Angle Between Vectors  Projecting One Vector onto.
6.4 Vectors and Dot Products

6.4 Vectors and Dot Products
APPLICATIONS OF TRIGONOMETRY

APPLICATIONS OF TRIGONOMETRY
Vectors in the Plane Peter Paliwoda.

Vectors in the Plane Peter Paliwoda.
Multiplication with Vectors

Multiplication with Vectors
6.4 Vectors and Dot Products The Definition of the Dot Product of Two Vectors The dot product of u = and v = is Ex.’s Find each dot product.

6.4 Vectors and Dot Products The Definition of the Dot Product of Two Vectors The dot product of u = and v = is Ex.’s Find each dot product.
Section 9.5: Equations of Lines and Planes

Section 9.5: Equations of Lines and Planes
1.1 – 1.2 The Geometry and Algebra of Vectors.  Quantities that have magnitude but not direction are called scalars. Ex: Area, volume, temperature, time,

1.1 – 1.2 The Geometry and Algebra of Vectors.  Quantities that have magnitude but not direction are called scalars. Ex: Area, volume, temperature, time,
Vectors Precalculus. Vectors A vector is an object that has a magnitude and a direction. Given two points P: & Q: on the plane, a vector v that connects.

Vectors Precalculus. Vectors A vector is an object that has a magnitude and a direction. Given two points P: & Q: on the plane, a vector v that connects.
H.Melikyan/12001 Vectors Dr.Hayk Melikyan Departmen of Mathematics and CS

H.Melikyan/12001 Vectors Dr.Hayk Melikyan Departmen of Mathematics and CS
Section 10.2a VECTORS IN THE PLANE. Vectors in the Plane Some quantities only have magnitude, and are called scalars … Examples? Some quantities have.

Section 10.2a VECTORS IN THE PLANE. Vectors in the Plane Some quantities only have magnitude, and are called scalars … Examples? Some quantities have.
1 © 2011 Pearson Education, Inc. All rights reserved 1 © 2010 Pearson Education, Inc. All rights reserved © 2011 Pearson Education, Inc. All rights reserved.

1 © 2011 Pearson Education, Inc. All rights reserved 1 © 2010 Pearson Education, Inc. All rights reserved © 2011 Pearson Education, Inc. All rights reserved.
Copyright © 2009 Pearson Addison-Wesley 7.4-1 7 Applications of Trigonometry and Vectors.

Copyright © 2009 Pearson Addison-Wesley Applications of Trigonometry and Vectors.

Similar presentations

Ads by Google