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Physics 218 Lecture 3. Dr. David Toback. Checklist for Today. Things that were due last Thursday : Chapter 1 reading Read all handouts from web page Things that are due yesterday (Monday) : WebCT warm-ups (FCI, Math Assess, etc…) Math Quizzes 1 through 10 Things that are due today :
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Physics 218Lecture 3 Dr. David Toback Physics 218, Lecture III
Checklist for Today • Things that were due last Thursday: • Chapter 1 reading • Read all handouts from web page • Things that are due yesterday (Monday): • WebCT warm-ups (FCI, Math Assess, etc…) • Math Quizzes 1 through 10 • Things that are due today: • Reading for Chapter 2 • Chapter 2 Lecture Questions • For this week and/or due next Monday: • Recitation: Lab materials, start Ch. 1 on WebCT • All HW1 problems on WebCT due Monday Physics 218, Lecture III
Describing Motion Interested in two key ideas: • How objects move as a function of time • Kinematics • Chapters 2 and 3 • Why objects move the way they do • Dynamics • Do this in Chapters 4 and 5 Physics 218, Lecture III
Chapter 2: Motion in 1-Dimension • Today: Velocity & Acceleration • Equations of Motion • Some calculus (derivatives) • Thursday: • More calculus (integrals) • Problems Physics 218, Lecture III
Notes before we begin • This chapter is a good example of a set of material that is best learned by doing examples • We’ll do some examples today • Lots more next time… Physics 218, Lecture III
Equations of Motion We want Equationsthat describe • Where am I as a function of time? • How fast am I moving as a function of time? • What direction am I moving as a function of time? • Is its velocity changing? Etc. Physics 218, Lecture III
Motion in One Dimension • Where is the car? • X=0feet at t0=0 sec • X=22feet at t1=1sec • X=44feet at t2=2sec • Since the car’s position is changing (i.e., moving) we say this car has “velocity” or “speed” • Plot position vs. time • How do we get the velocity from the graph? Physics 218, Lecture III
Velocity Questions: • How fast is my position changing? • What would my speedometer read? • What is my instantaneous Velocity? Physics 218, Lecture III
How do we Calculate Velocity? • Define Velocity:“Change in position during a certain amount of time” • Math: Calculate from the Slope: The “Change in position as a function of time” • Change in Vertical divided by the Change in Horizontal • Velocity =DX/Dt • Change: D Physics 218, Lecture III
Constant Velocity • Equation of Motion for this example is a straight line • Write this as: • X = bt • Slope is constant • Velocity is constant • Easy to calculate • Same everywhere Physics 218, Lecture III
Moving Car • A harder example: • X = ct2 • What’s the velocity at t=1 sec? • Want to calculate the “Slope” here Physics 218, Lecture III
Math Digression: Derivatives • To find the slope at time t, just take the “derivative” • For X=ct2, Slope = V =dx/dt =2ct • “Gerbil” derivative method • If X= atn V=dx/dt=natn-1 • “Derivative of X with respect to t” • More examples • X= qt2 V=dx/dt=2qt • X= ht3 V=dx/dt=3ht2 Physics 218, Lecture III
Common Mistakes The trick is to remember what you are taking the derivative “with respect to” More Examples (with a=constant): • What if X= 2a3tn? • Why not dx/dt = 3(2a2tn)? • Why not dx/dt = 3n(2a2tn-1)? • What if X= 2a3? • What is dx/dt? • There are no t’s!!! dx/dt = 0!!! • If X=22 feet, what is the velocity? =0!!! Physics 218, Lecture III
Check: Constant Position • X = C = 22 feet • V = slope = dx/dt = 0 • Check Physics 218, Lecture III
Check: Constant Velocity • Car is moving • X=0 feet at t0=0 sec • X=22feet at t1=1 sec • X=44feet at t2=2 sec • What is the equation of motion? • X = bt with b=22ft/sec • V = dX/dt V= b = 22ft/sec • Check Physics 218, Lecture III
Check: Non-Constant Velocity • X = ct2 with c=11ft/sec2 • V = dX/dt = 2ct • The velocity is: • “non-Constant” • a “function of time” • “Changes with time” • V=0ft/s at t0=0 sec • V=22ft/s at t1=1 sec • V=44 ft/s at t2=2sec Physics 218, Lecture III
Acceleration • If your velocity is changing, you are “accelerating” • You hit the accelerator in your car to speed up at a stop light • (Ok…It’s true you also hit it to stay at constant velocity, but that’s because friction is slowing you down…we’ll get to that later…) • How quickly is the velocity changing? That’s our Acceleration Physics 218, Lecture III
Acceleration • Acceleration is the “Rate of change of velocity” • Said differently: “How fast is the Velocity changing?” “What is the change in velocity as a function of time?” Physics 218, Lecture III
Example You have an equation of motion where: X = X0 + V0t + ½at2 where X0, V0 , and a are constants. What is the velocity and the acceleration? V = dx/dt = 0 + V0 + at • Remember that the derivative of a constant is Zero!! Accel = dV/dt =d2x/dt2 =0 + 0 + a Physics 218, Lecture III
Position, Velocity and Acceleration • All three are related • Velocity is the derivative of position with respect to time • Acceleration is the derivative of velocity with respect to time • Acceleration is the second derivative of position with respect to time • Calculus is REALLY important • Derivatives are something we’ll come back to over and over again Physics 218, Lecture III
Important Equations of Motion If the acceleration is constant Position, velocity and Acceleration are vectors. More on this in Chap 3 Physics 218, Lecture III
Conceptual Example • If the velocity of an object is zero, does it mean that the acceleration is zero? • If the acceleration is zero, does that mean that the velocity is zero? Physics 218, Lecture III
Car Crash Test Design You are designing a crash test setup for a car maker. You can accelerate a car from rest with a constant acceleration of 1.00 m/s2 so you can make the car crash into a wall. (This is the last time you will see numbers in a problem in lecture). • If the path is 200m long, what is the velocity of the car just before/as it hits the wall? • For the same acceleration, if you want the car to hit the wall with a speed of 30m/s (about 60 mi/hr), what minimum length must you have? Physics 218, Lecture III
Next Time • Textbook Reading and Reading Questions: • None (Chap 3 assigned on Thursday) • Homework: Math Quizzes and Chap 1 • Math Quizzes were due Monday • Work all Ch 1 probs before recitation • Start WebCT for Ch 1 before recitation • Chapter 1 HW due next Monday • Recitation: Ask TA for help on hard HW problems • Lab: Read VP Manual before lab • Thursday: more example problems Physics 218, Lecture III
End of Lecture Notes Physics 218, Lecture III
Decelerating Car You are driving a car along a straight highway when you put on the brakes. The initial velocity is 15.0m/s to the right, and it takes 5.0s to slow the car down until it is moving at 5.0m/s to the right. What is the car’s average acceleration? Physics 218, Lecture III
Examples • Can a car have uniform speed and non-constant velocity? • Can an object have a positive average velocity over the last hour, and a negative instantaneous velocity? Physics 218, Lecture III
Constant Velocity • This example: • X = bt • Slope is constant • Velocity is constant • Easy to calculate • Same everywhere Physics 218, Lecture III
More Questions on the Car Crash • What is the distance traveled? • What is the total displacement? • What is the average speed? • Is the average speed the same as the average velocity? • What is the instantaneous velocity at all times? Physics 218, Lecture III
Reference Frames Frame of reference: • Need to refer to some place as the origin • Draw a coordinate axis • We define everything from here • Always draw a diagram!!! Physics 218, Lecture III
Displacement Where are you? I.e, What is your displacement? Well…relative to where? Example: I’m 10 blocks north east of Kyle field What do we need to know? Where does the motion start? x0? • x0 is relative to the origin • x0 meters from the origin When does the motion start? t0? If the motion started here, call this x0 Physics 218, Lecture III
Vectors vs. Scalars Let’s say we traveled on a path like in the figure • Distance traveled from the origin is aScalar (like your car odometer). • Displacement from the origin is aVector • Has a distance and a direction from the origin • Speed is a scalar • Velocity is a vector • Negative distance? • Displacement? Scalar Distance traveled is 100m Vector Displacement is 40m East Physics 218, Lecture III
Another reason to care about vectors • It turns out that nature has decided that the directions don’t really care about each other. • Example: You have a position in X, Y and Z. If you have a non-zero velocity in only the Y direction, then only your Y position changes. The X and Z directions could care less. (I.e., they don’t change). Represent these ideas with Vectors Physics 218, Lecture III
Acceleration • An object is accelerating if it’s “velocity is changing as a function of time” • Acceleration = dv/dt • Acceleration and velocity can be pointing in different directions • How? • What is the difference between average acceleration and instantaneous acceleration? Physics 218, Lecture III
Displacement Where are you? I.e, What is your displacement? Well…relative to where? Example: I’m 10 blocks north east of Kyle field What do we need to know? Where does the motion start? x0? • x0 is relative to the origin • x0 meters from the origin When does the motion start? t0? If the motion started here, call this x0 Physics 218, Lecture III
Average Velocity • Average speed • Average velocity Total time = 10sec Avg Speed = 100m/10s = 10m/s Avg Velocity = (40m East)/10s = 4m/s East Physics 218, Lecture III
Instantaneous Velocity Average and Instantaneous Velocity • Average is “over a period of time” • I.e., How many miles you traveled in a day • Instantaneous is how fast are you going “right now” • Car example: • Instantaneousis more like your speedometer. • Averageis taking how far you traveled in the last hour and and dividing by an hour (includes the stops at the gas station) Physics 218, Lecture III
Instantaneous Cont… • V=Dx/Dt (use total change in x, t: average) • (instantaneous) • Magnitude of instantaneous velocity is always the same as the instantaneous speed • Why? In the last example, is the average velocity the same as the average speed? • Distance and displacement become identical in the limit that they become infinitesimally small Physics 218, Lecture III
Calculus 1 • Why are we doing math in a Physics class? • Believe it or not, Calculus and Classical mechanics were developed around the same time, and they essentially enabled each other. • Calculus basically IS classical mechanics • Bottom line: If you can’t do Calculus you can’t REALLY do physics. • It’s true you can do some simple problems Physics 218, Lecture III
Advice • You really need to be comfortable differentiating! • If you aren’t, do lots of problems in a introductory calculus book and take lots of math quizzes • The “rate” at which things “change” will be really big in everything we do • If you are struggling with the problems in the handout get help now • This stuff is going to go by quickly! Physics 218, Lecture III
Overview • I’m not going to teach you calculus • The goals are: • Teach (hopefully remind) you about how to think about how things “change as a function of time” • Teach you how to take a derivative (and why you take derivatives) so you can get by until you get to it in your calculus class • Diagrams are vital again! • Units here will really help (there is a good example of this in problem 1-9 on the Calculus handout). Physics 218, Lecture III
Some Notation • Let’s do some definitions • Define “define” • Example: t0 0 sec • We can always make a definition, the idea is to make one that is “useful” • Another example: X = 22 meters X0 • Define D as “the change in” Physics 218, Lecture III