University Physics: Mechanics

1. University Physics: Mechanics Ch2. MOTION ALONG A STRAIGHT LINE Lecture 3 Dr.-Ing. Erwin Sitompul http://zitompul.wordpress.com

2. Announcement for IE 14.10.09 17.30–18.30 : Class session 19.00–20.15 : Quiz 1 21.10.09 Graduation Day, No class 28.10.09 17.30–18.30 : Class session & Make-up Quiz 1 19.00–20.15 : Discussion of Quiz 1 04.11.09 18.30–20.30 : Mid-term Examination University Physics: Mechanics

3. Announcement for IT 23.10.09 17.30–18.30 : Class session 19.00–20.15 : Quiz 1 30.10.09 17.30–18.30 : Class session & Make-up Quiz 1 19.00–20.15 : Discussion of Quiz 1 06.11.09 18.30–20.30 : Mid-term Examination University Physics: Mechanics

4. Solution of Homework 2: Aprilia vs. Kawasaki An Aprilia and a Kawasaki are separated by 200 m when they start to move towards each other at t = 0. The Aprilia moves with initial velocity 5 m/s and acceleration 4 m/s2. The Kawasaki runs with initial velocity 10 m/s and acceleration 6 m/s2. 200 m (a) Determine the point where the two motorcycles meet each other. University Physics: Mechanics

5. Solution of Homework 2: Aprilia vs. Kawasaki • Possible answer • Both motorcycles meet after 5 seconds • Where? Thus, both motorcycles meet at a point 75 m from the original position of Aprilia or 125 m from the original position of Kawasaki. University Physics: Mechanics

6. Solution of Homework 2: Aprilia vs. Kawasaki (b) Determine the velocity of Aprilia and Kawasaki by the time they meet each other. • What is the meaning of negative velocity? University Physics: Mechanics

7. Free Fall Acceleration • A free falling object accelerates downward constantly (air friction is neglected). • The acceleration is a = –g = –9.8 m/s2, which is due to the gravitational force near the earth surface. • This value is the same for all masses, densities and shapes. • With a = –g = –9.8 m/s2, Accelerating feathers and apples in a vacuum University Physics: Mechanics

8. Example: Niagara Free Fall In 1993, Dave Munday went over the Niagara Falls in a steel ball equipped with an air hole and then fell 48 m to the water. Assume his initial velocity was zero, and neglect the effect of the air on the ball during the fall. (a) How long did Munday fall to reach the water surface? Niagara Falls University Physics: Mechanics

9. Example: Niagara Free Fall In 1993, Dave Munday went over the Niagara Falls in a steel ball equipped with an air hole and then fell 48 m to the water. Assume his initial velocity was zero, and neglect the effect of the air on the ball during the fall. (b) What was Munday’s velocity as he reached the water surface? or University Physics: Mechanics

10. Example: Niagara Free Fall In 1993, Dave Munday went over the Niagara Falls in a steel ball equipped with an air hole and then fell 48 m to the water. Assume his initial velocity was zero, and neglect the effect of the air on the ball during the fall. (c) Determine Munday’s position and velocity at each full second. University Physics: Mechanics

11. Example: Baseball Pitcher A pitcher tosses a baseball up along a y axis, with an initial speed of 12 m/s. (a) How long does the ball take to reach its maximum height? University Physics: Mechanics

12. Example: Baseball Pitcher A pitcher tosses a baseball up along a y axis, with an initial speed of 12 m/s. (b) What is the ball’s maximum height above its release point? University Physics: Mechanics

13. Example: Baseball Pitcher A pitcher tosses a baseball up along a y axis, with an initial speed of 12 m/s. (c) How long does the ball take to reach a point 5.0 m above its release point? • Both t1 and t2 are correct • t1 when the ball goes up, t2 when the ball goes down University Physics: Mechanics

14. University Physics: Mechanics Ch3. VECTOR QUANTITIES Lecture 3 Dr.-Ing. Erwin Sitompul http://zitompul.wordpress.com

15. Vectors and Scalars • A vector quantity has magnitude as well as direction. • Some physical quantities that are vector quantities are displacement, velocity, and acceleration. • A scalar quantity has only magnitude. • Some physical quantities that are scalar quantities are temperature, pressure, energy, mass, and time. • A displacement vector represents the change of position. • Both magnitude and direction is needed to fully specify a displacement vector. • The displacement vector, however, tells nothing about the actual path. University Physics: Mechanics

16. Adding Vectors Geometrically • Suppose that a particle moves from A to B and then later from B to C. • The overall displacement (no matter what its actual path) can be represented with two successive displacement vectors, AB and BC. • The net displacement of these two displacements is a single displacement from A to C. • AC is called the vector sum (or resultant) of the vectors AB and BC. • The vectors are now redrawn and relabeled, with an italic symbol and an arrow over it. • For handwriting, a plain symbol and an arrow is enough. University Physics: Mechanics

17. Adding Vectors Geometrically • Two vectors can be added in either order. • Three vectors can be grouped in any way as they are added. University Physics: Mechanics

18. Adding Vectors Geometrically • The vector is a vector with the same magnitude as but the opposite direction. Adding the two vectors would yield • Subtracting can be done by adding . University Physics: Mechanics

19. Components of Vectors • Adding vectors geometrically can be tedious. • An easier technique involves algebra and requires that the vectors be placed on a rectangular coordinate system. • For two-dimensional vectors, the x and y axes are usually drawn in the drawing plane. • A component of a vector is the projection of the vector on an axis. University Physics: Mechanics

20. Components of Vectors • Note, that the angle θ is the angle that the vector makes with the positive direction of the x axis. • The calculation of θ is done in counterclockwise directions. What is the value of θ on the figure above? θ = 324.46° or –35.54° University Physics: Mechanics

21. Components of Vectors • Vectors with various sign of components are shown as below: University Physics: Mechanics

22. Components of Vectors Which of the indicated methods for combining the x and y components of vector are proper to determine that vector? University Physics: Mechanics

23. Components of Vectors Example: A small airplane leaves an airport on an overcast day and it is later sighted 215 km away, in a direction making an angle of 22° east of due north. How far east and north is the airplane from the airport when sighted? Solution: Thus, the airplane is 80.54 km east and 199.34 km north of the airport. University Physics: Mechanics

24. Trigonometric Functions Sine Cosine Tangent University Physics: Mechanics

25. Unit Vectors • A unit vector is a vector that has a magnitude of exactly 1 and points in a particular direction. • The unit vectors in the positive directions of the x, y, and z axes are labeled • Unit vectors are very useful for expressing other vectors: University Physics: Mechanics

26. Adding Vectors Geometrically • Vectors can be added geometrically by subsequently linking the head of one vector with the tail of the other vector. • The addition result is the vector that goes from the tail of the first vector to the head of the last vector. University Physics: Mechanics

27. Adding Vectors by Components • Another way to add vectors is to combine their components axis by axis. University Physics: Mechanics

28. Adding Vectors by Components Component Notation Magnitude-angle Notation where In the figure below, find out the components of . University Physics: Mechanics

29. Adding Vectors by Components Desert Ant University Physics: Mechanics

30. Trivia A bear walks 5 km to the south. Resting a while, it continues walking 5 km east. Then, it walks again 5 km to the north and the bear reaches its initial position. What is the color of the bear? 5 km,south 5 km,north 5 kmeast Polar Bear with White Fur University Physics: Mechanics

31. Homework 3: The Beetles Two beetles run across flat sand, starting at the same point. The red beetle runs 0.5 m due east, then 0.8 m at 30° north of due east. The green beetle also makes two runs; the first is 1.6 m at 40° east of due north. What must be (a) the magnitude and (b) the direction of its second run if it is to end up at the new location of red beetle? 2nd run? 1st run 2nd run 1st run University Physics: Mechanics