Chapter 1 – Concepts of Motion

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Presentation transcript:

Chapter 1 – Concepts of Motion On your white boards, try creating a way to describe the motion of Mr. Cleese walking. http://www.youtube.com/watch?v=IqhlQfXUk7w&feature=related Sect. 1.1

Motion and the Particle Model Chp 1.2

A dust particle setting to the floor at constant speed. In groups with your white boards, create a particle motion diagram for: A dust particle setting to the floor at constant speed. A ball dropped from the roof of a building. A descending rocket slowing to make a soft landing on Mars. 1. 3. 2. Chp 1.2

These would be position vectors Let’s look more closely at the ball being dropped from the roof of a building. These would be displacement vectors. Sect. 1.3

Velocity is thus a “displacement” per “time”. Sec 1.4

Some definitions: Speed and Velocity Units “I’m travelling 90 kph.” – this is a speed, which is a scalar quantity. “I’m travelling due North at 90 kph.”—this is a velocity, which is a vector quantity. Units Speed and Velocity have the same units. Some typical choices for units are: miles hour km meters second Sec 1.4

Average Velocity vs. Instantaneous Velocity

Acceleration Acceleration is defined as the change in velocity with respect to time. Chp 1.5

You throw a ball straight up in the air You throw a ball straight up in the air. At the top the acceleration is: Up Down Zero

Acceleration Let’s take a ball and throw it directly upward into the air. What does the velocity vector look like at points A., B., and C.? What does the acceleration vector look like at points A., B., and C? B. A. C. Chp 1.5

Acceleration Let’s take a ball and throw it directly upward into the air. What is the acceleration at point A? B. A. C. Chp 1.5

Motion John walks forward 20 meters in 2 seconds. He then stands still for 1 second. Next, he walks backwards 30 meters in 2 seconds. He then slowly moves forward 50 meters over 10 seconds. position time velocity time Chp 1.6

At t=0 the car is s=10meters. Where is the at 6 seconds? velocity 40m/s time 3s 6s

Let’s try solving a problem: Sound travels at 331 m s If you are a bat, and you bounce a sound wave off a bug 2.0 meters away… … how long does it take for that sound wave to get back to you from the time that you sent it?

First thing that you do in problem solving is always: Draw a Picture 2 meters And, write down what you know: Distance between bat and bug = 2.0 meters Speed of Sound = 331 m/s

Distance between bat and bug = 2.0 meters Speed of Sound = 331 m/s If you don’t know what to do next, try thinking about a similar problem that you do know. For example: If you are traveling 90kph, and you traveled for 2 hours, how far did you go? From experience you know that you take 90 km/hr • 2 hours Let’s put that into word : velocity • time = distance Or: v • t = s

v • t = s So, in this problem: v = 330 m/s s = 4.0 meters Distance between bat and bug = 2 meters Speed of Sound = 330 m/s 2 meters v • t = s So, in this problem: v = 330 m/s s = 4.0 meters and t is the variable we want to solve for. .0120845921s =.012 s Chp 1.9

Rules for significant figures: Counting Significant Figures 4.322 0.4322 4.3220 400 Scientific Notation Multiplication of Significant Figures When multiplying (or dividing) your result should have the same number of significant digits as the measured value with the least number of significant digits. For example: 4.32 * 4.3 = Addition of Significant Figures When adding (or subtracting) you keep the largest last significant digit. Sect 1.7

Let’s try an example: The Hubble Deep Field Image contains 2.1·103 galaxies and it covers 1/9,891,000th of the entire sky. Our galaxy contains about 432 billion suns. With this information, approximate the total number of suns in the Universe. Sect 1.7

How many sig. figs. did your answer have? 1 2 3 4 5 6 7 8 9 Response Grid

Units of Measurements 95% of the human population uses SI Units. Only three countries don’t: U.S. Liberia Sultan of Oman Sect. 1.8

1012 109 106 103 100 1,000,000,000,000 1,000,000,000 1,000,000 1,000 1 Tera- Giga- Mega- Kilo- T G M k Sect. 1.8

100 10-1 10-2 10-3 10-6 10-9 10-12 1 .1 .01 .001 .000001 .000000001 .000000000001 deci- centi- milli- micro- nano- pico- d c m  n p Sect. 1.8

Describe the position, velocity, and acceleration profiles for the following case: Motion Detector The Cart is given a brief “kick”. It travels up the ramp, momentarily comes to rest at the top of the ramp, and then rolls back down.

Position time Velocity time Acceleration time

What is the acceleration of the car at the top? Up Down Zero Something else

Let’s try using graphs to solve question 1.21. The light turns green and a bicyclist starts forward with a constant acceleration of 1.5 m/s2. How far must she travel to reach a speed of 7.8m/s?

Make a prediction of what the position vs. time, velocity vs Make a prediction of what the position vs. time, velocity vs. time and acceleration vs. time graphs are going to look like for the following cases: A person walking forward at a constant slow speed for 5 seconds. s t A person walking forward at a constant fast speed for 5 seconds. A person starting at rest, then walking forward starting out slow and ending up fast while attempting a constant acceleration over a 5 second time period v t a A person walking forward at a constant fast speed for 10 meters, quickly turning around and running back to the start all over a 5 second time period. t

From chapter 1 you should be able to: Describe position, velocity, and acceleration using: words pictures (particle models) with vectors graphs You should be able to correctly use scientific notation, significant figures, and remember to include proper units and labeling everywhere.