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Describing Motion

Describing Motion. unit 6.1 year 10. Introduction. A typical physics course concerns itself with a variety of broad topics. One such topic is mechanics - the study of the motion of objects. Introduction.

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Describing Motion

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  1. Describing Motion unit 6.1 year 10

  2. Introduction • A typical physics course concerns itself with a variety of broad topics. One such topic is mechanics - the study of the motion of objects.

  3. Introduction • As we focus on the language, principles, and laws that describe and explain the motion of objects, your efforts should center on internalizing the meaning of the information.

  4. Introduction • Avoid memorizing the information; and avoid abstracting the information from the physical world that it describes and explains. Rather, contemplate the information, thinking about its meaning and its applications.

  5. Kinematics • Kinematics is the science of describing the motion of objects using words, diagrams, numbers, graphs, and equations. The goal of any study of kinematics is to develop mental models that serve to describe (and ultimately, explain) the motion of real-world objects.

  6. Kinematics • We will investigate the words used to describe the motion of objects. That is, we will focus on the language of kinematics. The hope is to gain a comfortable foundation with the language that is used throughout the study of mechanics.

  7. Kinematics • We will study such terms as scalars, vectors, distance, displacement, speed, velocity and acceleration. These words are used with regularity to describe the motion of objects. Your goal should be to become very familiar with their meaning.

  8. Scalars and Vectors • Scalars are quantities that are fully described by a magnitude (or numerical value) alone. • Vectors are quantities that are fully described by both a magnitude and a direction.

  9. Scalars and Vectors

  10. Scalars and Vectors • Categorize each quantity as being either a vector or a scalar. • 5 m • 30 m/sec, East • 5 km., North • 20 degrees Celsius • 4000 Calories Scalar Vector Vector Scalar Scalar

  11. Distance and Displacement • Distance is a scalar quantity that refers to "how much ground an object has covered" during its motion. • Displacementis a vector quantity that refers to "how far out of place an object is"; it is the object's overall change in position.

  12. Distance and Displacement • Use the diagram to determine the resulting displacement and the distance traveled by the skier during these three minutes.

  13. Distance and Displacement • The skier covers a distanceof (180 m + 140 m + 100 m) = 420 m • and has a displacement of 140 m, rightward.

  14. Distance and Displacement • What is the distance and the displacement of the race car drivers in the Bathurst 1000? • Distance = 1000 km. • Displacement = 0 km. as they finish where they started

  15. Speed and Velocity • Just as distance and displacement have distinctly different meanings (despite their similarities), so do speed and velocity.

  16. Speed • Speed is a scalar quantity that refers to "how fast an object is moving." Speed can be thought of as the rate at which an object covers distance.

  17. Velocity • Velocity is a vector quantity that refers to "the rate at which an object changes its position.” As such, velocity is direction aware. One must include direction information in order to fully describe the velocity of the object.

  18. Velocity • The direction of the velocity vector is simply the same as the direction that an object is moving. If an object is moving downwards, then its velocity is described as being downwards. So an airplane moving towards the west with a speed of 300 km/hr has a velocity of 300 km/hr, west.

  19. Calculating Average Speed and Average Velocity

  20. Calculating Average Speed and Average Velocity • Q: While on vacation, Lisa Carr traveled a total distance of 440 km. Her trip took 8 hours. What was her average speed? v= speed d = distance travelled t = time taken to travel the distance v = d/t = 440/8 = 55km/hr

  21. Average Speed versus Instantaneous Speed • Since a moving object often changes its speed during its motion, it is common to distinguish between the average speed and the instantaneous speed. • Instantaneous Speed - the speed at any given instant in time. • Average Speed - the average of all instantaneous speeds; found simply by a distance/time ratio.

  22. Calculating Average Speed and Average Velocity The physics teacher walks 4 m East, 2 m South, 4 m West, and finally 2 m North. The entire motion lasted for 24 seconds. Determine the average speed and the average velocity.

  23. Calculating Average Speed and Average Velocity The physics teacher walked a distance of 12 meters in 24 seconds; thus, his average speed was 0.50 m/s. However, since his displacement is 0 meters, his average velocity is 0 m/s.

  24. Calculating Average Speed and Average Velocity Use the diagram to determine the average speed and the average velocity of the skier during these three minutes.

  25. Calculating Average Speed and Average Velocity

  26. Calculating Average Speed and Average Velocity • The skier has an average speed of (420 m) / (3 min) = 140 m/min • and an average velocity of (140 m, right) / (3 min) = 46.7 m/min, right

  27. Sum it up Speed and velocity are kinematic quantities that have distinctly different definitions. Speed, being a scalar quantity, is the rate at which an object covers distance. The average speed is the distance (a scalar quantity) per time ratio. Speed is ignorant of direction.

  28. Sum it up On the other hand, velocity is a vector quantity; it is direction-aware. Velocity is the rate at which the position changes. The average velocity is the displacement or position change (a vector quantity) per time ratio.

  29. Measuring motion • Study text book (SCI FOCUS 4) pages 208 – 209 to gain knowledge on the tools and methods used to actually take measurements of motion.

  30. Graphing motion • Graphs are very useful in representing the motion of an object travelling in a straight line.

  31. Distance-time graphs • Distance–time graphs show the total distance travelled by an object as time progresses. • Time is always placed on the horizontal axis and distance on the vertical.

  32. Distance-time graph

  33. Speed–time graphs • A graph of speed against time gives picture of what is happening in the motion of an object. Time is placed on the horizontal axis. • If the object is getting faster, the graph rises. If it is slowing, the graph falls. Constant speed gives a flat graph. • The area under a speed–time graph gives the distance that the object has travelled up to that point.

  34. Speed–time graphs

  35. References • SCI FOCUS 4 – student text and teachers resource • www.physicsclassroom.com

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