Relative Motion.

Slides:

Advertisements

Similar presentations

Acceleration Acceleration Velocity-time graph Questions.

Advertisements

Aim: How can we calculate average velocity when distance is unknown? Do Now: What is the average velocity between A and B? Velocity (m/s) Time (s)

Acceleration. Recall:  Acceleration is the rate at which velocity increases or decreases  If an object is accelerating is not experiencing uniform motion.

Acceleration & Distance Uniform Acceleration, Starting from rest

Introduction to Motion. Speed How fast something moves The rate of change in position A rate of motion.

Motion, Speed, and Velocity

Motion An object is in motion when it changes it position relative to to reference point.

Motion Chapter 12.

Describing Motion: Speed & Velocity. What Is Motion? Motion is when an object changes place or position. To properly describe motion, you need to use.

What Is Speed? All the runners in the one kilometer race will start at exactly the same time. They will all go exactly the same distance. One runner.

Objectives 1.Define and calculate acceleration 2.describe how the physics definition of acceleration differs from the everyday definition of acceleration.

Kinetic Energy A moving object has energy because of its motion. This energy is called kinetic energy.

Motion SWBAT define speed and acceleration; relate acceleration to change in speed; calculate distance, speed, and acceleration.

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

10.1 MEASURING MOTION. I CAN…  explain how motion is dependent of the observers frame of reference.  explain motion in terms of position, displacement,

Shrinking Moon Explanation on next slide. Velocity Is a description of an object’s speed and direction. formula is the same as for speed Velocity=

Speed and Velocity What is speed, velocity and acceleration?

Acceleration & Speed How fast does it go?. Definition of Motion Event that involves a change in the position or location of something.

Motion Graph Practice For each of the following: Create the missing, X vs. t, V vs. t, a vs. t graphs A Motion Map Determine the displacement covered by.

Solving Quadratics. Methods for Solving Quadratics Graphing Factoring Square Root Method Completing the Square Quadratic Formula.

How Far? _________ (d) ______________________________________ To get to the store go 2-miles east, turn right and go 3-miles south. How far will you travel.

 Acceleration is the rate that velocity changes over time.  An object is accelerating if ◦ Its speed changes ◦ Its direction changes ◦ Both its speed.

REVISION What two parts make up the stopping distance of a vehicle?

Velocity - time graph 1. The velocity – time graph shows the motion of a particle for one minute. Calculate each of the following. (a) The acceleration.

Motion. Motion- the change in the position of an object with respect to time and its reference point Motion is RELATIVE Reference point/ frame of reference:

Setting Up Motion Equations Part IV: A New Hope. Write out the formula that provides a solution for the question A tiger runs at a constant velocity V.

WARM UP EVALUATING EXPRESSIONS Evaluate the expression for the given value of the variable (Lesson 2.5). 1.-3(x) when x = 9 2.4(-6)(m) when m = (-n)(-n)

Motion Recognizing, Describing, and Measuring Motion.

Acceleration. The rate of change in velocity Acceleration The rate of change in velocity Examples…. –Speeding up Positive acceleration –Slowing down.

 You can use weighted averages to solve uniform motion problems when the objects you are considering are moving at constant rates or speeds.

Introduction to Motion Motion in One Dimension. Basic Vocabulary Scalar quantity: A quantity with only a magnitude. (weight, time) Vector quantity: A.

Speed – Time Graphs. SlopeExampleInterpretation high positive value high acceleration rapid increase in speed low positive value low acceleration slow.

VELOCITY & ACCELERATION VELOCITY *Describes both the speed & direction of an object.

How to Calculate Speed and Acceleration

Sketching Motion Graphs Interpreting Motion Graphs Constant Velocity Acceleration Distance/

Resolve the vector into x & y components 40.0 m/s at 45 o SoW.

Motion in One Dimension Mechanics – study of the motion of objects and the related concepts of force and energy. Dynamics – deals with why objects move.

Motion Year 10 Chapter Do Now: Michael is caught in the hallway without his tie on by Mrs. Fox. He is able to run 18.7 m in 3.1 s before she.

CH. 2 NOTES Abbreviated. Distance vs. Displacement Distance – how far an object travels (meters) Displacement – straight line path between two points.

UNIT TWO: Motion, Force, and Energy  Chapter 4Motion  Chapter 5Force  Chapter 6Newton’s Laws of Motion  Chapter 7 Work and Energy.

Chapter 11: Motion Section 11.3 Acceleration.

Motion. What is Speed? Speed- The distance an object is moving over a certain period of time Speed tells you how fast or slow an object is moving Instantaneous.

Physics Support Materials Higher Mechanics and Properties of Matter b Solutions to Problems - Equations of Motion 27,27, 28, 33, 34, 35,28,33,34,35, Click.

Motion; Speed; Velocity; Acceleration

MOTION Chapter 11.

What is Motion?.

Graph 2: A car travels at a constant speed of 6 m/s

Speed How fast does it go?.

Consider a car moving with a constant, rightward (+) velocity - say of +10 m/s. If the position-time data for such a car were.

Motion Review Challenge

Speed and Velocity What is speed, velocity and acceleration?

Graphing Motion Walk Around

EQ: How Can We Measure Speed?

Motion Unit Miss McDonald Science 8

Kinematics Formulae & Problems Day #1

Chapter 4, Section 2 Graphs of Motion.

Speed & Velocity.

A car is decelerated to 20 m/s in 6 seconds

CH. 2 Notes Abbreviated.

What does the word “acceleration” mean to you?

Distance, Direction and Position

Motion Section 3 Acceleration

Speed Velocity Acceleration

Speed, Velocity, & Acceleration

Chapter 4, Section 2 Graphs of Motion.

Unit II – Speed, Motion, Velocity and Acceleration

Motion.  When describing something that is moving, you are comparing it with something that is assumed to be stationary (not moving).  The frame of.

Motion, Speed, and Velocity

Presentation transcript:

Relative Motion

Frame of Reference (F.O.R.) A frame of reference in physics, may refer to a coordinate system or set of axes within which to measure the position, orientation, and other properties of objects in it, or it may refer to an observational reference frame tied to the state of motion of an observer. http://en.wikipedia.org/wiki/Frame_of_reference

Situation Problem involving more than one object in motion Example:

Solution Use relative motion to reduce number of variables Example:

Problem #1 Two cars are traveling down a highway in the same direction. Car A is traveling at speed v1 and currently a distance x behind Car B that is traveling at v2. Given that v1 > v2 express the time t it takes Car A to catch Car B in terms of v1, v2, and x. v1 A v2 B x

“Hard Solution” x1 = distance for Car A at time t x2 = distance for Car B at time t x1 = x2 x1 = v1t x2 = x + v2t v1t = x + v2t v1t - v2t = x (v1-v2)t = x Relative Speed

Problem #2 Two runners are sprinting to the finish line of a 200 m race. Runner #1 is traveling at 5 m/s and is accelerating at 0.7 m/s2. Runner #2 is traveling at 7 m/s and is accelerating at 0.2 m/s2. Runner #2 is currently 100 m from the finish line and Runner #1 is 110 m from the finish line. How many seconds after this point in time will Runner #1 catch Runner #2?

Use Quadratic Formula or Graphing Solution F.O.R. is Runner #2  vo=0, a1=0 Runner #1  vo= -2 m/s, a = 0.5 m/s2, xo= -10 m When Runner #1 catches Runner #2 x=0 x = xo + vot + ½ at2 0 = -10 + (-2t) + 0.25t2 Use Quadratic Formula or Graphing Calculator to solve t = -3.5 s and t = 11.5 s

Problem #3 Two boats are sailing toward a marina. Boat A is traveling at 8 m/s and is currently 50 m behind Boat B that is traveling at 6 m/s. How many seconds will it take Boat A to catch Boat B? Same basic problem as #1