KINEMATICS. File:The Horse in Motion.jpg - Wikimedia Foundation. Monday, June 17, 13

Similar documents
KINEMATICS WHERE ARE YOU? HOW FAST? VELOCITY OR SPEED WHEN YOU MOVE. Typical Cartesian Coordinate System. usually only the X and Y axis.

Displacement, Velocity & Acceleration

RECAP!! Paul is a safe driver who always drives the speed limit. Here is a record of his driving on a straight road. Time (s)

Section Distance and displacment

What You Will Learn In This Chapter. Displacement Vector Distance Velocity Vectors Acceleration Vectors Motion with constant Acceleration

Distance vs. Displacement, Speed vs. Velocity, Acceleration, Free-fall, Average vs. Instantaneous quantities, Motion diagrams, Motion graphs,

Motion Chapter 3, Section 1: Distance, Displacement, Speed, Velocity

C 2. The average speed of a car that travels 500 km in 5 hours is a. 10 km/h. b km/h. c. 100 km/h. d. 1,000 km/h

Which car/s is/are undergoing an acceleration?

Ch 2. Describing Motion: Kinematics in 1-D.

Created by T. Madas CALCULUS KINEMATICS. Created by T. Madas

Speed how fast an object is moving (also, the magnitude of the velocity) scalar

Speed ( v ) is the distance an object travels during a given time interval divided by the time interval.

CHAPTER 2: Describing Motion: Kinematics in One Dimension

Acceleration. 3. Changing Direction occurs when the velocity and acceleration are neither parallel nor anti-parallel

MOTION, DISTANCE, AND DISPLACEMENT Q: What is motion? A: Motion is any change in the position or place of an object. is the study of motion (without

40 Chapter 2 Kinematics

Chapter 2. Preview. Objectives One Dimensional Motion Displacement Average Velocity Velocity and Speed Interpreting Velocity Graphically

Speed. Change of Distance (in meters) Change of Time (in seconds) Step 2: Formula. 100m in 10sec. 200m in 10sec T. 200m in 20sec.

Chapter 2 Describing Motion

What is Motion? any physical movement or change in position or place, relative to a reference point. Movement. Reference Point

Linear Motion 1. Scalars and Vectors. Scalars & Vectors. Scalars: fully described by magnitude (or size) alone. That is, direction is not involved.

AP Physics Free Response Practice Kinematics ANSWERS 1982B1 2

CHAPTER 2 DESCRIBING MOTION: KINEMATICS IN ONE DIMENSION

Motion in One Dimension

What is a Vector? A vector is a mathematical object which describes magnitude and direction

PHYSICS - CLUTCH CH 02: 1D MOTION (KINEMATICS)

Velocity, Speed, and Acceleration. Unit 1: Kinematics

Chapter 2. Motion along a straight line

Chapter 2 Kinematics in One Dimension:

5) A stone is thrown straight up. What is its acceleration on the way up? 6) A stone is thrown straight up. What is its acceleration on the way down?

DESCRIBING MOTION: KINEMATICS IN ONE DIMENSION. AP Physics Section 2-1 Reference Frames and Displacement

Motion Graphs Refer to the following information for the next four questions.

Solving Problems In Physics

Definitions. Mechanics: The study of motion. Kinematics: The mathematical description of motion in 1-D and 2-D motion.

1. How could you determine the average speed of an object whose motion is represented in the graphs above?

Kinematics II Mathematical Analysis of Motion

AP Physics 1 Summer Assignment (2014)

Describing Mo tion. Speed and Velocity. What is speed?

3.3 Acceleration An example of acceleration Definition of acceleration Acceleration Figure 3.16: Steeper hills

Kinematics II Mathematical Analysis of Motion

MITOCW MIT8_01F16_W01PS05_360p

Chapter 2: Motion along a straight line

Velocity vs. Time. time (sec)

PHYSICS Kinematics in One Dimension

Chapter 2. Motion In One Dimension

Motion along a straight line

Unit 1 Test Review Physics Basics, Movement, and Vectors Chapters 2-3

One-Dimensional Motion

Physics 103 Laboratory Fall Lab #2: Position, Velocity and Acceleration

Four Types of Motion We ll Study

Position, Speed and Velocity Position is a variable that gives your location relative to an origin. The origin is the place where position equals 0.

If we plot the position of a moving object at increasing time intervals, we get a position time graph. This is sometimes called a distance time graph.

Introduction to Kinematics. Motion, Forces and Energy

Jan 31 8:19 PM. Chapter 9: Uniform Rectilinear Motion

Chapter 8 : Motion. KEY CONCEPTS [ *rating as per the significance of concept ]

Chapter 2 Section 2: Acceleration

Chapter 2. Motion along a straight line

Chapter 2. Motion along a straight line. We find moving objects all around us. The study of motion is called kinematics.

Worksheet 1: One-Dimensional Kinematics

Lecture 2. 1D motion with Constant Acceleration. Vertical Motion.

Chapter 2: Kinematics

PHYSICS Principles and Problems. Chapter 2: Representing Motion

Motion along a straight line. Physics 11a. 4 Basic Quantities in Kinematics. Motion

2/18/2019. Position-versus-Time Graphs. Below is a motion diagram, made at 1 frame per minute, of a student walking to school.

Chapter 2. Motion along a straight line

Kinematics Motion in 1-Dimension

To conduct the experiment, each person in your group should be given a role:

James T. Shipman Jerry D. Wilson Charles A. Higgins, Jr. Omar Torres. Chapter 2 Motion Cengage Learning

Car Lab: Results. Were you able to plot: Position versus Time? Velocity versus Time? Copyright 2010 Pearson Education, Inc.

Physics 11 Kinematics Review: Vectors, Displacement, Velocity, Acceleration, & Kinematics Equations

Remember... Average rate of change slope of a secant (between two points)

Important Vocabulary Speed vs Velocity Acceleration Graphs of Motion Momentum

Page 1 / 15. Motion Unit Test. Name: Motion ONLY, no forces. Question 1 (1 point) Examine the graphs below:

Kinematics Motion in 1-Dimension

Position-versus-Time Graphs

Motion Unit Review 1. To create real-time graphs of an object s displacement versus time and velocity versus time, a student would need to use a

PHYS1100 Practice problem set, Chapter 2: 6, 10, 13, 17, 22, 24, 25, 34, 42, 50, 55, 65, 71, 82

Lecture 2. 1D motion with Constant Acceleration. Vertical Motion.

Displacement, Velocity, and Acceleration AP style

Unit 1 Parent Guide: Kinematics

Introduction to 1-D Motion Distance versus Displacement

average speed instantaneous origin resultant average velocity position particle model scalar

Chapter 2. Motion along a straight line

SCIENCE 1206 Unit 3. Physical Science Motion

Chapter 3: Introduction to Motion

an expression, in terms of t, for the distance of the particle from O at time [3]

AP Physics 1 Kinematics 1D

STAAR Science Tutorial 21 TEK 6.8D: Graphing Motion

PHYS 1401 Homework #1 Solutions

9. This graph depicts the motion of an object. During which time interval is the object at rest?

Fall 2008 RED Barcode Here Physics 105, sections 1 and 2 Please write your CID Colton

Chapter 3 - RATE IN MECHANICAL SYSTEMS. Graphing Foldable /10

Position-Time Graphs

Worksheet 3. Sketch velocity vs time graphs corresponding to the following descriptions of the motion of an object.

Physics I Exam 1 Spring 2015 (version A)

Graphing Motion (Part 1 Distance)

11.3 Acceleration. What Is Acceleration? How are changes in velocity described?

Chapter 2 Linear Motion

Department of Physics. ( Al Ansar International School, Sharjah) ( ) Project Work Term 1. IGCSE Physics Grade 9. Students Name: Grade / Section:

Transcription:

KINEMATICS File:The Horse in Motion.jpg - Wikimedia Foundation 1

WHERE ARE YOU? Typical Cartesian Coordinate System usually only the X and Y axis meters File:3D coordinate system.svg - Wikimedia Foundation 2

File:Distancedisplacement.svg - Wikimedia Commons Distance Scalar Quantity Difference between two positions Displacement Vector Quantity How to get from one position to another WHEN YOU MOVE 3

HOW FAST? Speed Scalar Quantity Change in DISTANCE over TIME Velocity Vector Quantity Change in DISPLACEMENT over TIME units for both (m/s) File:RansomEliOldsOldsPirate.jpg - Wikimedia Commons 4

VELOCITY OR SPEED A person jogs eight complete laps around a quarter mile track in a total time of 12.5 minutes. Calculate (a) the average speed and (b) the average velocity, in miles per hour (mph) 5

VELOCITY DETAILS Direction can change the results Often positive or negative represents the direction like forwards and backwards Average Velocity often will not match the average speed Instantaneous Velocity - speed and direction at an instant. 6

GETTING FASTER Acceleration Vector Quantity Change in VELOCITY over Time m / s / s or m / s 2 Positive sign is not the same as getting faster Negative sign is not the same as deceleration 7

x f = x i + vt + 1 2 at 2 Where you are at the end Where you started Your initial velocity The time (duration) If your speed changed 9

v f = v i + at No Distance Your initial velocity Your final velocity The time (duration) a = v f v i t If your speed changed can be rearranged 11

EQUATION 3 VELOCITY BASED ON POSITION v f 2 = v i 2 + 2ad 12

SIMPLE PLUG-IN EXAMPLE A car accelerates from rest to a maximum speed of 75 m/s in 0.2 minutes. What was its acceleration? How far did it travel in this time? 13

SIMPLE PLUG-IN EXAMPLE Vf = 75 m/s A car accelerates from rest to a maximum speed of 75 m/s in 0.2 minutes. What was its acceleration? How far did it travel in this time? t = 0.2 min = 12 s Vi = 0 m/s a =? 13

PICK AN EQUATION Vf = 75 m/s x f = x i + vt + 1 2 at 2 t = 12 s v f = v i + at Vi = 0 m/s a =? v f 2 = v i 2 + 2ad 14

PICK AN EQUATION Vf = 75 m/s x f = x i + vt + 1 2 at 2 t = 12 s Vi = 0 m/s v f = v i + at a = 6.25 m/s 2 now d = or xf =? v f 2 = v i 2 + 2ad 15

KINEMATIC GRAPHS 16

CONSTANT POSITION Position Time 17

CONSTANT POSITIVE VELOCITY Position Time 18

CONSTANT NEGATIVE VELOCITY Position Time 19

POSITIVE VELOCITY - POSITIVE ACCELERATION Position positive slope Greater positive slope Time 20

POSITIVE VELOCITY - NEGATIVE ACCELERATION Position positive slope with a lower value Time positive slope 21

NEGATIVE VELOCITY - NEGATIVE ACCELERATION Position negative slope Time negative slope with a lower value 22

NEGATIVE VELOCITY - POSITIVE ACCELERATION Position negative slope Time negative slope with a higher value 23

VELOCITY / TIME GRAPH 20 m/s Velocity 8s Time Slope = Acceleration 24

VELOCITY / TIME GRAPH 20 m/s Velocity 8s Time Area = Distance 25

READING A GRAPH A plot of the position of a car as a function of time is shown in the diagram. Find the velocity of the car during each section of the graph. Velocity = Slope V= 6m / 4s V = +1.5 m/s 26

READING A GRAPH A plot of the velocity of a car as a function of time is shown in the diagram. Find the acceleration of the car during each section of the graph. acceleration = Slope a = 22 m/s / 4s a = 5.5 m/s 2 27

READING A GRAPH A plot of the velocity of a car as a function of time is shown in the diagram. Find the displacement of the car during each section of the graph. Displacement = Area = ½ (22 m/s 4s) D = 44 m 28

SIMPLE MOTION A car starts with a velocity of 0 m/s and accelerates at 7 m/s 2. what is the velocity after 8 seconds? what is the velocity as the car passes 25 m when does the car pass 100m when is the car s velocity 22 m/s 29

SIMPLE MOTION A car starts with a velocity of 0 m/s and accelerates at 7 m/s 2. what is the velocity after 8 seconds? what is the velocity as the car passes 25 m when does the car pass 100m when is the car s velocity 22 m/s v f = v i + at A C B D 30

SIMPLE MOTION A truck starts with a velocity of 45 m/s and accelerates at -6 m/s 2. what is the velocity after 4.2 seconds? where is the truck after 4.2 seconds? when is the truck s velocity 0 m/s where is the truck when it has a velocity of 0 m/s 31

SIMPLE MOTION A truck starts with a velocity of 45 m/s and accelerates at -6 m/s 2. what is the velocity after 4.2 seconds? where is the truck after 4.2 seconds? when is the truck s velocity 0 m/s where is the truck when it has a velocity of 0 m/s v f = v i + at A C B D 32

COMBINED MOTION A car starts at rest and accelerates at +5.6 m/s2. At the same moment, a truck passes by at a constant velocity of 30 m/s. when will the car pass the truck? where will the car pass the truck? Which would win a 200 m race? File:Castro street corner w. market street 01.JPG - Wikimedia Foundation 33

COMBINED MOTION A car starts at rest and accelerates at +5.6 m/s 2. At the same moment, a truck passes by at a constant velocity of 30 m/s. x f = x i + vt + 1 2 at 2 34

PRACTICE PROBLEM You have 6.0 hours to travel a distance of 140 km by bicycle. How long will it take you to travel the first half at an average speed of 5.8 m/s? In the second half of the ride, you need to increase your average speed to make up for lost time. If you can maintain an average speed of 7 m/s, will you be able to reach your destination on time? 35

SAMPLE PROBLEM A driver traveling at 30.0 km/hr sees the light turn red at the intersection. If his reaction time is 0.600 s, and the car can decelerate at 4.50 m/s 2, find the stopping distance of the car. 38

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback