Vector Notation Text uses italics with arrow to denote a vector: Also used for printing is simple bold print: A When dealing with just the magnitude of.

Slides:

Advertisements

Similar presentations

Vectors and Two-Dimensional Motion

Advertisements

General Physics (PHYS101)

Chapter 3 Vectors.

Vector Components. Coordinates  Vectors can be described in terms of coordinates. 6.0 km east and 3.4 km south6.0 km east and 3.4 km south 1 m forward,

1 Vectors and Two-Dimensional Motion. 2 Vector Notation When handwritten, use an arrow: When handwritten, use an arrow: When printed, will be in bold.

Vectors and Two-Dimensional Motion

Chapter 3 Vectors.

Ch. 3, Kinematics in 2 Dimensions; Vectors. Vectors General discussion. Vector  A quantity with magnitude & direction. Scalar  A quantity with magnitude.

Chapter 3 Vectors Coordinate Systems Used to describe the position of a point in space Coordinate system consists of A fixed reference point called.

Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley. Chapter 4: Motion in 2 and 3 dimensions To introduce the concepts and notation.

Introduction and Vectors

Chapter 3 Vectors and Two-Dimensional Motion. Vector vs. Scalar Review All physical quantities encountered in this text will be either a scalar or a vector.

Adding Vectors, Rules When two vectors are added, the sum is independent of the order of the addition. This is the Commutative Law of Addition.

Chapter 3 Vectors and Two-Dimensional Motion. Vector vs. Scalar A vector quantity has both magnitude (size) and direction A scalar is completely specified.

Chapter 3, Vectors. Outline Two Dimensional Vectors –Magnitude –Direction Vector Operations –Equality of vectors –Vector addition –Scalar product of two.

Vectors You will be tested on your ability to: 1.correctly express a vector as a magnitude and a direction 2. break vectors into their components 3.add.

Chapter 3 Vectors. Coordinate Systems Used to describe the position of a point in space Coordinate system consists of a fixed reference point called the.

Unit 3 Vectors and Motion in Two Dimensions. What is a vector A vector is a graphical representation of a mathematical concept Every vector has 2 specific.

In this chapter we will learn about vectors.  properties, addition, components of vectors When you see a vector, think components! Multiplication of vectors.

3.1 Introduction to Vectors.  Vectors indicate direction; scalars do not  Examples of scalars: time, speed, volume, temperature  Examples of vectors:

Vector Quantities We will concern ourselves with two measurable quantities: Scalar quantities: physical quantities expressed in terms of a magnitude only.

Adding Vectors Graphically CCHS Physics. Vectors and Scalars Scalar has only magnitude Vector has both magnitude and direction –Arrows are used to represent.

Chapter 3 Vectors and Two-Dimensional Motion. Vector Notation When handwritten, use an arrow: When handwritten, use an arrow: When printed, will be in.

Chapter 3 Vectors and Two-Dimensional Motion Vectors and Scalars A scalar is a quantity that is completely specified by a positive or negative number.

Vector Quantities Vectors have ▫magnitude ▫direction Physical vector quantities ▫displacement ▫velocity ▫acceleration ▫force.

2-D motion. 2 Scalars and Vectors A scalar is a single number that represents a magnitude –Ex. distance, mass, speed, temperature, etc. A vector is a.

Chapter 3 Vectors. Coordinate Systems Used to describe the position of a point in space Coordinate system consists of a fixed reference point called the.

Types of Coordinate Systems

VECTORS. Pythagorean Theorem Recall that a right triangle has a 90° angle as one of its angles. The side that is opposite the 90° angle is called the.

 To add vectors you place the base of the second vector on the tip of the first vector  You make a path out of the arrows like you’re drawing a treasure.

Chapter 3: Vectors EXAMPLES

Vectors: Magnitude and direction Examples for Vectors: force – acceleration- displacement Scalars: Only Magnitude A scalar quantity has a single value.

Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley. Chapter 3: Vectors To introduce the concepts and notation for vectors:

VECTORS AND TWO- DIMENSIONAL MOTION Properties of Vectors.

Chapter 2 Motion in One Dimension. Free Fall All objects moving under the influence of only gravity are said to be in free fall All objects moving under.

Chapter 4 Vector Addition When handwritten, use an arrow: When printed, will be in bold print: A When dealing with just the magnitude of a vector in print,

(3) Contents Units and dimensions Vectors Motion in one dimension Laws of motion Work, energy, and momentum Electric current, potential, and Ohm's law.

Opening Question If we travel 10km north and then 15km at an angle of 30˚ south of east how far are we from our start point?

Two-Dimensional Motion and Vectors

Chapter 3 Vectors. Vector quantities  Physical quantities that have both numerical and directional properties Mathematical operations of vectors in this.

Chapter 3 Vectors. Coordinate Systems Used to describe the ___________of a point in space Coordinate system consists of – A fixed _____________point called.

Chapter 1 Introduction.  Length (m)  Mass (kg)  Time (s) ◦ other physical quantities can be constructed from these three.

Kinematics & Dynamics in 2 & 3 Dimensions; Vectors First, a review of some Math Topics in Ch. 1. Then, some Physics Topics in Ch. 4!

Two-Dimensional Motion and Vectors. Scalars and Vectors A scalar is a physical quantity that has magnitude but no direction. – –Examples: speed, volume,

Vectors Vectors vs. Scalars Vector Addition Vector Components

Ying Yi PhD Chapter 3 Vectors and Two- Dimensional Motion 1 PHYS HCC.

Part 2 Kinematics Chapter 3 Vectors and Two-Dimensional Motion.

Chapter 3 Vectors. Vector quantities  Physical quantities that have both numerical and directional properties Mathematical operations of vectors in this.

Outline Addition and subtraction of vectors Vector decomposition

1.3 Vectors and Scalars Scalar: shows magnitude

Chapter 3: Vectors.

Two-Dimensional Motion and Vectors

Lesson 3.1 Introduction to Vectors

Chapter 3 Vectors.

Two-Dimensional Motion & Vectors

Chapter Vectors.

Ch. 3: Kinematics in 2 or 3 Dimensions; Vectors

Kinematics & Dynamics in 2 & 3 Dimensions; Vectors

Vectors - It’s What’s for Dinner

Chapter 4 Vector Addition

Vectors and Scalars AP Physics C.

Two Dimensional Motion Unit 3.3

Vectors and Scalars AP Physics C.

Week 2 Vectors in Physics.

Presentation transcript:

Vector Notation Text uses italics with arrow to denote a vector: Also used for printing is simple bold print: A When dealing with just the magnitude of a vector in print, an italic letter will be used: A or | | The magnitude of the vector has physical units The magnitude of a vector is always a positive number When handwritten, use an arrow:

Adding Vectors When adding vectors, their directions must be taken into account Units must be the same Graphical Methods Use scale drawings Algebraic Methods More convenient

To Add Vector’s Graphically

Graphical Addition Create a scale Draw the vectors based on the scale Put the tail of one vector on the tip of the other The resultant vector is the one that goes from the tail of the first vector to the tip of the second. Use a protractor, ruler, and your established scale to get the value of the resultant vector.

Problem at 30° above the x-axis at 20° below the x-axis Find graphically.

Multiplying or Dividing a Vector by a Scalar The result of the multiplication or division of a vector by a scalar is a vector The magnitude of the vector is multiplied or divided by the scalar If the scalar is positive, the direction of the result is the same as of the original vector If the scalar is negative, the direction of the result is opposite that of the original vector

Component Method of Adding Vectors Graphical addition is not recommended when High accuracy is required If you have a three-dimensional problem Component method is an alternative method It uses projections of vectors along coordinate axes

Problem at 30° above the x-axis at 20° below the x-axis Find graphically.

Problem at 30° above the x-axis at 20° below the x-axis Find by components.

Rules of Adding Vectors Commutative law: Associative law: Vector subtraction: Algebra still works: can be rewritten as

Example 3.5 – Taking a Hike A hiker begins a trip by first walking 25.0 km southeast from her car. She stops and sets up her tent for the night. On the second day, she walks 40.0 km in a direction 60.0° north of east, at which point she discovers a forest ranger’s tower. Determine the components of the hiker’s resultant displacement for the trip. Find an expression for in terms of unit vectors.