Chapter 3.2 – Drawing Vectors

Slides:

Advertisements

Similar presentations

Solving 2-D Vectors Graphically

Advertisements

Aim: How can we describe resultant force (net force)?

Chapter 3: Two Dimensional Motion and Vectors

Vector Fundamentals Notes

12.7 Geometric Vectors. Vector: a quantity that has both magnitude and direction. A tail B head vectors can be placed anywhere on a grid, not necessarily.

Kinematics Chapters 2 & 3.

Vectors and Vector Addition Honors/MYIB Physics. This is a vector.

Graphical Analytical Component Method

Vector addition, subtraction Fundamentals of 2-D vector addition, subtraction.

Vectors 1D kinematics 2D kinematics Newton’s laws of motion

Physics: Chapter 3 Vector & Scalar Quantities

Physics and Physical Measurement Topic 1.3 Scalars and Vectors.

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 Chapter 3, Sections 1 and 2. Vectors and Scalars Measured quantities can be of two types Scalar quantities: only require magnitude (and proper.

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

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.

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.

CHAPTER 5 FORCES IN TWO DIMENSIONS

Kinematics and Dynamics

Vector Basics. OBJECTIVES CONTENT OBJECTIVE: TSWBAT read and discuss in groups the meanings and differences between Vectors and Scalars LANGUAGE OBJECTIVE:

Vectors and Applications BOMLA LacyMath Summer 2015.

Unit 3-1: 2-Dimensional Vectors. A vector is any quantity that has both magnitude and direction. A 2-Dimensional vector is drawn at some angle with the.

Scalar Quantities Scalar quantities are measurements that have only magnitude (size) but no direction. Examples of scalar quantities are; Distance Speed.

Adding Vectors on the Same Line When two vectors are in the same direction it is easy to add them. Place them head to tail and simply measure the total.

VECTORS. Vectors A person walks 5 meters South, then 6 meters West. How far did he walk?

2-D Force Problems. 7 kg 2N 3N 8N Find the direction and magnitude of the acceleration of the box.

Vector Addition Chapter 3 – Part 1. Vectors represent magnitude and direction Vectors vs. scalars? Vectors can be added graphically A student walks from.

Two Dimensional Motion we will now analyze motion in the horizontal plane which (like all planes) is two dimensional we will first use vector diagrams.

Vectors and Scalars. Edexcel Statements A scalar quantity is a quantity that has magnitude only and has no direction in space Examples of Scalar Quantities:

Vectors Vectors vs. Scalars Vector Addition Vector Components

Scalars and Vectors Physical Quantities: Anything that can be measured. Ex. Speed, distance, time, weight, etc. Scalar Quantity: Needs only a number and.

Physics and Physical Measurement Topic 1.3 Scalars and Vectors.

10/8 Do now The diagrams below represent two types motions. One is constant motion, the other, accelerated motion. Which one is constant motion and which.

3-1 INTRODUCTION TO SCALAR AND VECTORS CHAPTER 3.

Vectors Physics 1 st Six Weeks. Vectors vs. Scalars.

Principles of Technology/Physics in Context (PT/PIC) Chapter 4 Vector Quantities 1 Text p

Chapter 1-Part II Vectors

Lesson 12 – 7 Geometric Vectors

VECTORS Wallin.

Use the Force… To discuss what forces can do for them.

Unit IV Part A- Vectors.

Vectors Vector vs Scalar Quantities and Examples

Review for: Unit 2 – Vectors

Unit III Part A- Vectors

Magnitude The magnitude of a vector is represented by its length.

How do we add and subtract vectors?

Vectors What is a vector? Examples of vector quantities include:

Chapter 3 Projectile Motion

8-1 Geometric Vectors 8-2 Algebraic Vectors

Kinematics in 2 Dimensions Vectors

Scalars v. Vectors.

Algebraic Addition of Vectors

Chapter 3 part 1 Vectors and Vector Addition

Forces in Two Dimensions

The Graphical Method Write a list of procedures for adding vectors graphically. Check with a partner to see if your procedures are in order and that you.

Physics: Chapter 3 Vector & Scalar Quantities

Vector Addition Methods Graphical Method Component Method

Aim: What other details can be discussed about vectors?

Vector components Resolving Vectors.

Vector & Scalar Quantities

Introduction to 2D motion and Forces

Vectors A vector is a quantity which has a value (magnitude) and a direction. Examples of vectors include: Displacement Velocity Acceleration Force Weight.

Chapter 3.2 – Adding Vectors

Vectors A vector is a quantity which has a value (magnitude) and a direction. Examples of vectors include: Displacement Velocity Acceleration Force Weight.

Vector & Scalar Quantities

Presentation transcript:

Chapter 3.2 – Drawing Vectors

Adding Vectors The process of adding vectors has also been previously discussed in our section of Newton’s Laws. The net force was the result ( or resultant) of adding up all the force vectors. In that chapter, the rules for adding vectors were kept simple.

Practice: Find the Resultant (Net Force)

In this chapter, the task of adding vectors will be extended to more complicated cases in which the vectors are directed in directions other than purely vertical and horizontal directions.

There are a variety of methods for determining the magnitude and direction of the result of adding two or more vectors. The 2 Methods that we will learn how to use: 1. Pythagorean Theorem (using Trig) 2. Head – to – Tail Method ( using graphs)

Calculating Resultants Using the “Head – To – Tail” Method 1. Add the vectors by first attaching them head to tail. 2. Once all the vectors have been added head-to-tail, the resultant is then drawn from the tail of the first vector to the head of the last vector; i.e., from start to finish 3. Once the resultant is drawn, its length can be measured and converted to real units using the given scale. 4. The direction of the resultant can be determined by using a protractor and measuring its counterclockwise angle from the horizon.

EXAMPLE #1 Add the following vectors together and find the resultant 20 m, 45 deg. + 25 m, 300 deg. + 15 m, 210 deg. Scale: 1 cm = 5m

Step #2 Draw your vectors “Head – to- Tail” Draw the resultant in red. Draw the resultant from the start to finish.

The order in which you draw or attach) your vectors doesn’t matter, as long as your don’t change the magnitude or the direction.