Vectors and Motion in Two Dimensions

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Presentation transcript:

Vectors and Motion in Two Dimensions Chapter 3 Vectors and Motion in Two Dimensions Topics: Vectors, coordinate systems, and components Projectile motion Circular motion Sample question: The archer fish shoots a stream of water droplets at an insect. What determines the path that the droplets take through the air? Slide 3-1

Looking Back: What You Already Know From this class: In Chapter 1 you learned what a vector is and learned how to add vectors. In Chapter 2 you learned about motion in one dimension. Motion in two dimensions will build naturally on this foundation. From previous classes: You probably know that any two objects in free fall will undergo similar motions; if you drop two objects from the same height at the same time, they will hit the ground simultaneously. You might well have learned a bit about vectors in another course. Slide 3-2

Reading Quiz  Ax is the __________ of the vector A. magnitude x-component direction size displacement Answer: C Slide 3-3

Answer  Ax is the __________ of the vector A. direction Slide 3-4 Answer: C Slide 3-4

Reading Quiz The acceleration of a particle in projectile motion points along the path of the particle. is directed horizontally. vanishes at the particle’s highest point. is directed down at all times. is zero. Answer: D Slide 3-5

Answer The acceleration of a particle in projectile motion is directed down at all times. Answer: D Slide 3-6

Reading Quiz The acceleration vector of a particle in uniform circular motion points tangent to the circle, in the direction of motion. points tangent to the circle, opposite the direction of motion. is zero. points toward the center of the circle. points outward from the center of the circle. Answer: D Slide 3-7

Answer The acceleration vector of a particle in uniform circular motion points toward the center of the circle. Answer: D Slide 3-8

Vectors Slide 3-9

Vector Subtraction Slide 3-10

Acceleration Vectors Slide 3-11

Component Vectors and Components Slide 3-12

Checking Understanding Which of the vectors below best represents the vector sum P + Q?   Answer: A Slide 3-13

Answer Which of the vectors below best represents the vector sum P + Q?   Answer: A Slide 3-14

Checking Understanding Which of the vectors below best represents the difference P – Q?   Answer: B Slide 3-15

Answer Which of the vectors below best represents the difference P – Q?   Answer: B Slide 3-16

Checking Understanding Which of the vectors below best represents the difference Q – P?   Answer: C Slide 3-17

Answer Which of the vectors below best represents the difference Q – P?   Answer: C Slide 3-18

What are the x- and y-components of these vectors? 3, 2 2, 3 -3, 2 2, -3 -3, -2 Answer: B Slide 3-19

What are the x- and y-components of these vectors? 2, 3 Answer: B Slide 3-20

What are the x- and y-components of these vectors? Answer: B 3, 4 4, 3 -3, 4 4, -3 -3, -4 Slide 3-21

What are the x- and y-components of these vectors? Answer: B 4, 3 Slide 3-22

The following vectors have length 4.0 units. What are the x- and y-components of these vectors? 3.5, 2.0 -2.0, 3.5 -3.5, 2.0 2.0, -3.5 -3.5, -2.0 Answer: B Slide 3-23

The following vectors have length 4.0 units. What are the x- and y-components of these vectors? B. -2.0, 3.5 Answer: B Slide 3-24

The following vectors have length 4.0 units. What are the x- and y-components of these vectors? 3.5, 2.0 2.0, 3.5 -3.5, 2.0 2.0, -3.5 -3.5, -2.0 Answer: E Slide 3-25

The following vectors have length 4.0 units. What are the x- and y-components of these vectors? -3.5, -2.0 Answer: E Slide 3-26

Examples The labeled vectors each have length 4 units. For each vector, what is the component parallel to the ramp? The labeled vectors each have length 4 units. For each vector, what is the component perpendicular to the ramp? Slide 3-27

The diagram below shows two successive positions of a particle; it’s a segment of a full motion diagram. Which of the acceleration vectors best represents the acceleration between vi and vf?   Answer: D Slide 3-28

Answer The diagram below shows two successive positions of a particle; it’s a segment of a full motion diagram. Which of the acceleration vectors best represents the acceleration between vi and vf?   Answer: D Slide 3-29

Motion on a Ramp In the Soapbox Derby, young participants build cars with very low-friction wheels in which they roll down a hill. Cars racing on the track at Akron’s Derby Downs, where the national championship is held, begin on a 55 ft section of the track that is tipped 13° from the horizontal. What is the maximum possible acceleration of a car moving down this stretch of track? If a car starts from rest and accelerates at this rate for the full 55 ft, how fast will it be moving? A new ski area has opened that emphasizes the extreme nature of the skiing possible on its slopes. Suppose an ad intones “Free-fall skydiving is the greatest rush you can experience...but we’ll take you as close as you can get on land. When you tip your skis down the slope of our steepest runs, you can accelerate at up to 75% of the acceleration you’d experience in free fall.” What angle slope could give such an acceleration? Slide 3-30

Relative Motion An airplane pilot wants to fly due west from Spokane to Seattle. Her plane moves through the air at 200 mph, but the wind is blowing 40 mph due north. In what direction should she point the plane—that is, in what direction should she fly relative to the air? A skydiver jumps out of an airplane 1000 m directly above his desired landing spot. He quickly reaches a steady speed, falling through the air at 35 m/s. There is a breeze blowing at 7 m/s to the west. At what angle with respect to vertical does he fall? When he lands, what will be his displacement from his desired landing spot? Slide 3-31

Projectile Motion The horizontal motion is constant; the vertical motion is free fall: The horizontal and vertical components of the motion are independent. Slide 3-32

Projectile Motion In the movie Road Trip, some students are seeking to jump a car across a gap in a bridge. One student, who professes to know what he is talking about (“Of course I’m sure—with physics, I’m always sure.”), says that they can easily make the jump. He gives the following data: The car weighs 2100 pounds, with passengers and luggage. Right before the gap, there’s a ramp that will launch the car at an angle of 30°.The gap is 10 feet wide. He then suggests that they should drive the car at a speed of 50 mph in order to make the jump. If the car actually went airborne at a speed of 50 mph at an angle of 30° with respect to the horizontal, how far would it travel before landing? Does the mass of the car make any difference in your calculation? Slide 3-33

Broad Jumps A grasshopper can jump a distance of 30 in (0.76 m) from a standing start. If the grasshopper takes off at the optimal angle for maximum distance of the jump, what is the initial speed of the jump? Most animals jump at a lower angle than 45°. Suppose the grasshopper takes off at 30° from the horizontal. What jump speed is necessary to reach the noted distance? Slide 3-34

Circular Motion There is an acceleration because the velocity is changing direction. Slide 3-35

Circular Motion Old vinyl records are 12" in diameter, and spin at 33⅓ rpm when played. What’s the acceleration of a point on the edge of the record? Two friends are comparing the acceleration of their vehicles. Josh owns a Ford Mustang, which he clocks as doing 0 to 60 mph in a time of 5.6 seconds. Josie has a Mini Cooper that she claims is capable of a higher acceleration. When Josh laughs at her, she proceeds to drive her car in a tight circle at 13 mph. Which car experiences a higher acceleration? Slide 3-36