1. Professional Development Series June 18, 2005 The Physics of Tops presented by Luis A. Martínez-Pérez, Ph.D. Associate Professor Science Education Florida International University

2. Conceptual Ideas TOPS

3. Newton's 1st Law Newton's first law applies to an object at rest or else moving at constant velocity. It states simply that there can be no acceleration without forces. More technically: An object at rest or moving at a constant velocity will continue to do so unless acted upon by an external force.

4. Newton's 2nd Law The 2nd law of Newton describes what happens quantitatively when a force does act upon an object: Force of an object = mass x acceleration We thus see that the acceleration of an object is always proportional to the force acting on it. Double the force, and the acceleration doubles; halve the force and the acceleration is cut in half.

5. Newton's 3rd Law Newton's 2nd law deals with a single object on which a force is exerted. The 3rd and last law of motion discovered by Newton explains what happens to the object that is exerting the force. The 3rd law can be summarized by stating that: For every action there is an equal and opposite reaction.

6. Motion of an Object Position Velocity Acceleration

7. Position The first idea needed in describing the motion of an object is its position relative to some fixed reference point. This entails two ideas: the distance the object is away from the reference point, and also the direction relative to that reference point.

8. Average Velocity For an object in motion the concept of velocity is important. There are two types of velocity that can be defined. Suppose an object moves from one point to another in a certain time interval. The average velocity during that time interval is defined as: Average Velocity = Change in position divided by time

9. Instantaneous Velocity The average velocity only depends on the initial and final points of the travel - it knows nothing of the details of the motion between these points. For this reason one introduces the concept of instantaneous velocity, which applies to a single point, or time of the motion.

10. Average Acceleration The acceleration of an object describes the rate of change of velocity. Also just as with velocity, there are two types of acceleration. The first - the average acceleration - involves the change in instantaneous velocity over a given time interval: Average acceleration =change of velocity over time

11. We can also define the instantaneous acceleration at a point A as the limit of the average acceleration between point A and a nearby point B as the interval between A and B becomes zero: The instantaneous acceleration at A is the average acceleration between A and B as A approaches B. Instantaneous Acceleration

12. Rotational Motion

13. Circular motion Motion of a body about a fixed axis

14. When we discussed linear motion, we introduced three measures of such motion: position, velocity, and acceleration. For circular motion we can define analogous quantities: ■ Angular Position ■ Angular Velocity ■ Angular Acceleration

15. The first is the angular position, conventionally denoted by θ, as in the figure below. This is the angle at a particular instant in time that the object makes with respect to some fixed reference axis.

16. Angular Displacement One of the reasons that the description of circular motion in terms of angular displacement is so useful is that it can be applied to the motion of extended, rigid objects rotating about a fixed axis

17. Angular velocity In analogy with the concept of velocity for linear motion, the angular velocity for rotational motion can be defined. One first introduces the average angular velocity over a time by which the object moves from a point A on a circle to point B: Average angular velocity = change in angular position over time

18. The instantaneous angular velocity at a point B is then defined to be the average angular velocity between point A and a point B as the point A approaches point B: The instantaneous angular velocity at A is the average angular velocity between A and B as A approaches B. Instantaneous angular velocity

19. Angular acceleration The last analogy with linear motion is the concept of angular acceleration. As with angular velocity, one first introduces the average angular acceleration between two points A and B as A approaches B. Average angular acceleration = change in angular velocity over time

20. Instantaneous angular acceleration Instantaneous angular acceleration at A is defined to be the average angular acceleration between point A and a point B as the point A approaches B: The instantaneous angular acceleration at A is the average angular acceleration between A and B as A approaches B.

21. GRAVITY Newton's Law of Gravity Every particle attracts every other particle with a force that is proportional to the product of their masses and inversely proportional to the distance between them.

22. Sir Isaac Newton: The Universal Law of Gravitation CLICK HERE

23. Center of Gravity The center of gravity is a geometric property of any object. The center of gravity is the average location of the weight of an object.

24. Center of Gravity Activity

25. BALANCE

27. A force is a push or a pull. A force can give energy to an object causing the object to start moving, stop moving, or change its motion. Forces occur in pairs and can be either balanced or unbalanced. Balanced forces do not cause a change in motion. They are equal in size and opposite in direction.

28. Moment of inertia is the name given to rotational inertia, the rotational analog of mass for linear motion. It appears in the relationships for the dynamics of rotational motion. The moment of inertia must be specified with respect to a chosen axis of rotation.mass Moment of Inertia

29. For a point mass the moment of inertia is just the mass times the square of perpendicular distance to the rotation axis, I = mr2. That point mass relationship becomes the basis for all other moments of inertia since any object can be built up from a collection of point masses.point mass

30. Rotational Kinetic Energy

31. Kinetic energy is the energy of motion. An object which has motion - whether it be vertical or horizontal motion - has kinetic energy. There are many forms of kinetic energy - vibrational (the energy due to vibrational motion), rotational (the energy due to rotational motion), and translational (the energy due to motion from one location to another).

32. Recall that an object of a certain mass moving with particular speed will have an associated kinetic energy mass x speed2. An object spinning about an axis will also have associated with it a kinetic energy, composed of the kinetic energies of each individual part of the object. These individual contributions may be summed up to give an expression for the total kinetic energy of the spinning object: Rotational kinetic energy

33. Rotational kinetic energy = ½ moment of inertia x (angular speed) 2

34. is the resistive force that occurs when two surfaces travel along each other when forced together. It causes physical deformation and heat buildup.resistive forcesurfaces heat Friction

37. Catapult at the Miami Museum of Science

38. Projectile motion refers to the motion of an object projected into the air at an angle.

40. CLICK HERE

42. Physics Content Outline The Physics Classroom Newton’s Laws of Motion The Scribbling Top Projectile Motion Just Click on the Star of Your Choice Universal Law of Gravitation

43. CONTACT INFORMATION Luis A. Martínez-Pérez, Ph.D. Associate Professor Middle and Secondary Science Education College of Education EB 348B Florida International University University Park Miami, Florida 33199 Office Telephone: (305) 348-3215 Office Fax: (305) 348-2086 Home Fax: (305) 385-0005 E-mail: martinel@fiu.edumartinel@fiu.edu Web Page: http://www.fiu.edu/~sste/sste_index.htm http://www.fiu.edu/~sste/sste_index.htm