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LINEAR MOTION

LINEAR MOTION . Chapter 4. Puzzler. QUESTION:.

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LINEAR MOTION

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  1. LINEAR MOTION Chapter 4

  2. Puzzler QUESTION: • Suppose you and a pair of life preservers are floating down a swift river, as shown. You wish to get to either of the life preservers for safety. One is 3 meters downstream from you, and the other is 3 meters upstream from you. Which can you swim to in the shortest time? • The preserver upstream • The preserver downstream • Each swim requires the same time. downstream

  3. Puzzler Answer ANSWER: C To get a grip on this, pretend that you are in a swimming pool on a fast-moving ocean liner. If both life preservers are the same distance from you in the pool, swimming toward either would take the same time. The speed of the liner through the water makes no difference, just as it makes no difference to people playing shuffleboard or billiards. Can you see that, in the flowing river, you're like a person in a pool aboard a moving ocean liner—that swimming toward either preserver takes the same time? All objects have uniform motion; they are all in (dynamic) equilibrium.

  4. One-Dimensional Motion and Distance • Motion in one dimension refers to straight-line motion (Linear) • Example: train traveling on a straight track

  5. Motion and Frame of Reference • Motion • a change in position • Frame of reference • A point against which position is measured • Example: A train traveling between stations • It is in motion when measured against the track. • It is stationary when measured against a seat.

  6. DETECTING MOTION •  In order to see an object in motion, you need to compare it to a frame of reference, such as a stationary background. RELATIVE MOTION

  7. RELATIVE MOTION WEB SITES • http://www.phy.ntnu.edu.tw/java/relativeVelocity/relativeVelocity.html • Determine the displacement and distance for the journey illustrated below. • 120 m north, 57 m south, 5 minute rest, 78 m south, 40 m north, 67 m north, 99 m south, 7 minute rest, 42 m north.

  8. Displacement (x) vs. Distance (d) 5 m = 17 m • Displacement means straight line distance from the initial position to the final position (change in position) • Distance means the total length of the path traveled by an object. 7 m 5 m • Keep in mind that distance is the addition of all lengths of the path traveled by an object in all directions.

  9. Think: • How is it possible for a car to travel a distance of 5 miles, and have a displacement is equal to zero. • Drive around a very long block and return to the starting position. • Back out of your garage, drive 5 miles, and return to your garage.

  10. Average Velocity • Average velocity is total displacement divided by the time interval during which the displacement occurred. Average speed equation is written v = d/t v is average speed t is time d is distance

  11. Section 1 Displacement and Velocity Chapter 2 Average Velocity • The units can be determined from the equation. • SI Units: meters per second or m/s • Other Possible Units: mi/h, km/h, cm/year

  12. Classroom Practice Problems • A car travels 36 km to the north in 30.0 min. Find the average velocity in km/min and in km/h. • Answer: 1.2 km/min to the north or 72 km/h to the north • A car travels 100.0 km to the east. If the first half of the distance is driven at 50.0 km/h and the second half at a 100.0 km/h, what is the average velocity? • Answer: 66.7 km/h to the east

  13. Constant Velocity • Object maintains the same speed in the same direction • Example: Car travels at 35 km/h due east

  14. Speed • Speed does not include direction while velocity does. • Speed uses distance rather than displacement. • In a round trip, the average velocity is zero but the average speed is not zero.

  15. Velocity and Speed • Velocity describes motion with both a direction and a numerical value (a magnitude). • Speed has no direction, only magnitude.

  16. Graphing Motion Position (distance) vs. Time Graphs At rest, no change in position

  17. Graphing Motion Position (distance) vs. Time Graphs The objects shown by the yellow and blue lines are covering equal amounts of distance in equal amounts of time. The velocity of the object can be calculated by evaluating the slope of each line, or one point along each line. Yellow line (constant speed of 3 m/s) Blue line (constant speed of 1 m/s)

  18. Graphing Motion Position (distance) vs. Time Graphs The object represented by the yellow line is covering a greater amount of distance with each unit of time that passes. (it is speeding up) Changing distance over time or acceleration.

  19. Graphing Motion (position vs. time) • What type of motion does this graph show? • Answer: Constant speed (straight line) • What is the slope of this line? • Answer: 1 m/s • What is the average velocity? • Answer: 1 m/s

  20. Graphing Motion • Describe the motion of each object. • Answers • Object 1: constant velocity to the right or upward • Object 2: constant velocity of zero (at rest) • Object 3: constant velocity to the left or downward

  21. Puzzler QUESTION: Would this situation change if the life preservers were fixed in place relative to the swimmer and the river’s current? • Suppose you and a pair of life preservers are floating down a swift river, as shown. You wish to get to either of the life preservers for safety. One is 3 meters downstream from you, and the other is 3 meters upstream from you. Which can you swim to in the shortest time? • The preserver upstream • The preserver downstream • Each swim requires the same time.

  22. HOW CAN YOU TELL THAT AN OBJECT IS MOVING? • THE MOTION OF ONE OBJECT MAKES SENSE ONLY WHEN IT IS COMPARED TO ANOTHER OBJECT THAT HAS A DIFFERENT MOTION.

  23. SENSING MOTION • We cannot sense uniform motion (mechanical equilibrium) unless we can compare our motion to an object with different motion. • We can only sense changes in uniform motion, which is acceleration.

  24. THE FATHERS OF MOTION: Falling Objects • Aristotle (~300 BC) hypothesized that heavier objects fell faster than lighter objects. • Galileo (~1500’s) tested Aristotle’s hypothesis about falling objects and proved it wrong. • Sir Isaac Newton (late 1600’s) extended Galileo’s work into three laws of motion and the universal law of gravitation. • Newton showed that the universe ran according to natural laws.

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