3.3 Vectors in the Plane. Numbers that need both magnitude and direction to be described are called vectors. To represent such a quantity we use a directed.

Slides:

Advertisements

Similar presentations

Chapter 10 Vocabulary.

Advertisements

Section 4.1 – Vectors (in component form)

VECTORS IN A PLANE Pre-Calculus Section 6.3.

6.3 Vectors in the Plane Many quantities in geometry and physics, such as area, time, and temperature, can be represented by a single real number. Other.

Section 6.1b Direction Angles Velocity, Speed. Let’s start with a brain exercise… Find the unit vector in the direction of the given vector. Write your.

Introduction to Vectors March 2, What are Vectors? Vectors are pairs of a direction and a magnitude. We usually represent a vector with an arrow:

Digital Lesson Vectors.

6.3 Vectors Copyright © by Houghton Mifflin Company, Inc. All rights reserved. 1 Students will: Represent vectors as directed line segments. Write the.

Copyright © Cengage Learning. All rights reserved.

Copyright © Cengage Learning. All rights reserved.

APPLICATIONS OF TRIGONOMETRY

Vectors in the Plane Peter Paliwoda.

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 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:

Chapter 6 Additional Topics in Trigonometry

Geometric and Algebraic.  A vector is a quantity that has both magnitude and direction.  We use an arrow to represent a vector.  The length of the.

Coordinate Systems 3.2Vector and Scalar quantities 3.3Some Properties of Vectors 3.4Components of vectors and Unit vectors.

Geometry 7.4 Vectors. Vectors A vector is a quantity that has both direction and magnitude (size). Represented with a arrow drawn between two points.

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 in Plane Objectives of this Section Graph Vectors Find a Position Vector Add and Subtract Vectors Find a Scalar Product and Magnitude of a Vector.

TMAT 103 Chapter 11 Vectors (§ §11.7). TMAT 103 §11.5 Addition of Vectors: Graphical Methods.

Advanced Precalculus Notes 8.4 Vectors Vector: a quantity which has both magnitude (represented by length of arrow) and direction. If a vector represents.

Physics Quantities Scalars and Vectors.

Chapter 3 Vectors.

What you should learn: Represent vectors as directed line segments. Write the component forms of vectors. Perform basic vector operations and represent.

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.

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.

Warm up 1. Find the magnitude of this vector 2. A vector has Initial point (0,2) and terminal point (9,15). Write this vector in component form. 3. Find.

Introduction to Vectors Lesson Scalars vs. Vectors Scalars  Quantities that have size but no direction  Examples: volume, mass, distance, temp.

8.1 and 8.2 answers. 8.3: Vectors February 9, 2009.

Motion in 2 dimensions Vectors vs. Scalars Scalar- a quantity described by magnitude only. –Given by numbers and units only. –Ex. Distance,

8.4 Vectors. A vector is a quantity that has both magnitude and direction. Vectors in the plane can be represented by arrows. The length of the arrow.

Geometry 9.7 Vectors. Goals  I can name a vector using component notation.  I can add vectors.  I can determine the magnitude of a vector.  I can.

Copyright © Cengage Learning. All rights reserved. 6.3 Vectors in the Plane.

It’s time for Chapter 6… Section 6.1a Vectors in the Plane.

Section 6.6 Vectors. Overview A vector is a quantity that has both magnitude and direction. In contrast, a scalar is a quantity that has magnitude but.

Vectors Physics Book Sections Two Types of Quantities SCALAR Number with Units (MAGNITUDE or size) Quantities such as time, mass, temperature.

11.1 Vectors in the Plane.  Quantities that have magnitude but not direction are called scalars. Ex: Area, volume, temperature, time, etc.  Quantities.

OBJECTIVES: Represent vectors as directed line segments Write the component forms of vectors Perform basic vector operations and represent them graphically.

A.) Scalar - A single number which is used to represent a quantity indicating magnitude or size. B.) Vector - A representation of certain quantities which.

C H. 6 – A DDITIONAL T OPICS IN T RIGONOMETRY 6.3 – Vectors!

Copyright © Cengage Learning. All rights reserved. Vectors in Two and Three Dimensions.

Section 6.3 Vectors 1. The student will represent vectors as directed line segments and write them in component form 2. The student will perform basic.

11.5 Vectors in the Plane Do Now A man is at the top of a lighthouse 100 ft high and spots a ship in the ocean. His angle of depression to the ship is.

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 Def. A vector is a quantity that has both magnitude and direction. v is displacement vector from A to B A is the initial point, B is the terminal.

Vectors Def. A vector is a quantity that has both magnitude and direction. v is displacement vector from A to B A is the initial point, B is the terminal.

CHAPTER 3 VECTORS NHAA/IMK/UNIMAP.

6.1 – Vectors in the Plane.

VECTORS 6.6 “It’s a mathematical term, represented by

Scalars and Vectors.

Introduction to Vectors

Scalars Some quantities, like temperature, distance, height, area, and volume, can be represented by a ________________ that indicates __________________,

VECTORS Dr. Shildneck.

Copyright © Cengage Learning. All rights reserved.

6.3 Vectors in the Plane Ref. p. 424.

VECTORS Dr. Shildneck.

Vectors in the Plane.

Lesson 83 – Algebraic Vectors

Presentation transcript:

3.3 Vectors in the Plane

Numbers that need both magnitude and direction to be described are called vectors. To represent such a quantity we use a directed line segment. Initial Point Terminal Point

Notation Vectors are written as arrows. – The length of the arrow describes the magnitude of the vector. – The direction of the arrow indicates the direction of the vector… Vectors are written in bold in your book On the board we will use the notation below… PQu, v, or w

You can think of magnitude as size or amount, including units. To find the magnitude we use the distance formula EX– let u be represented by the directed line segment from P(0, 0) to Q (3,2) and let v be represented by the directed line segment from R (1,2) to S (4,4). Graph these vectors and find the magnitude.

Component form of the vector with initial point P = (p 1, p 2 ) and terminal point Q = (q 1, q 2 ) is given by PQ = = = v The magnitude (or length) of v is given by ||v|| =  (q 1,-p 1 ) 2 + (q 2,-p 2 ) 2 If ||v|| = 1 then it is called the unit vector

Example Find the component form and the magnitude of the vectors with initial point (1, 11) and terminal point (9,3)

Scalar multiplication Vector addition In operations with vectors, numbers are usually referred to as scalars. The resultant is the sum of two or more vectors added together.

Adding vectors u + v = Graphically-- Example= Let v = and w= So v + w =

Scalar multiplication 2u = Graphically-- Example= Let v = and w= So 2v =

Unit Vectors u = unit vector = v = 1 v ||v|| ||V|| Find the unit vector in the direction of w = 7j – 3i

We know a vector with the initial point at the origin is said to be in in standard position. u = Where a is the horizontal component and b is the vertical component NOW…… u = AKA v = ai + bj Where i is the horizontal component and j is the vertical component

IF u = -3i + 8j and v = 2i - j Find 2u – 3v

The positive angle between the x-axis and a positive vector How would you find this angle?

Find the direction angle of the vector u = 3i + 3j

Find the direction angle of the vector u = 3i - 4j

Applications of Vectors 2 ways to write vectors or u = ai + bj Each time we did this we made a graph…. (x, y) (cos , sin  ) u = cos  i, sin  j

Component Form v = ||v||(cos  )i + ||v||sin  j