Test Problems for Oscillatory motion (L9). Make sure you
... back to one platform. The time for the forward and return motion is ...
... back to one platform. The time for the forward and return motion is ...
F net = T
... If two objects, a uniform disk and a uniform sphere, have the same moment of inertia about their axes of rotation and the same angular velocity, then the disk has the larger rotational kinetic ...
... If two objects, a uniform disk and a uniform sphere, have the same moment of inertia about their axes of rotation and the same angular velocity, then the disk has the larger rotational kinetic ...
Tuesday, June 3, 2008
... The heavier the object, the bigger the inertia !! It is harder to make changes of motion of a heavier object than a lighter one. The same forces applied to two different masses result in different acceleration depending on the mass. ...
... The heavier the object, the bigger the inertia !! It is harder to make changes of motion of a heavier object than a lighter one. The same forces applied to two different masses result in different acceleration depending on the mass. ...
10 Motion Trial Test
... The diagram below shows a small section of ticker tape used to record the motion of a student pulling the tape through a ticker timer. The marked interval represents a time interval of 0.1 seconds. (a) What is the average speed (in cm/s) shown a during the marked interval? (b) Is the speed throughou ...
... The diagram below shows a small section of ticker tape used to record the motion of a student pulling the tape through a ticker timer. The marked interval represents a time interval of 0.1 seconds. (a) What is the average speed (in cm/s) shown a during the marked interval? (b) Is the speed throughou ...
Monday, September 24, 2007
... The heavier the object, the bigger the inertia !! It is harder to make changes of motion of a heavier object than a lighter one. The same forces applied to two different masses result in different acceleration depending on the mass. ...
... The heavier the object, the bigger the inertia !! It is harder to make changes of motion of a heavier object than a lighter one. The same forces applied to two different masses result in different acceleration depending on the mass. ...
Lab3_Force_Table
... You now have a system in equilibrium. The last hanger is called the equilibrant because it balances the system. 5) The resultant vector has the same magnitude as the Equilibrant, but points in the opposite direction. The Resultant angle will be θR = |180° - θEquilibrant|. To find the magnitude of th ...
... You now have a system in equilibrium. The last hanger is called the equilibrant because it balances the system. 5) The resultant vector has the same magnitude as the Equilibrant, but points in the opposite direction. The Resultant angle will be θR = |180° - θEquilibrant|. To find the magnitude of th ...
Wednesday, February 13, 2008
... Galileo’s statement on natural states of matter: Any velocity once imparted to a moving body will be rigidly maintained as long as the external causes of retardation are removed!! Galileo’s statement is formulated by Newton into the 1st law of motion (Law of Inertia): In the absence of external forc ...
... Galileo’s statement on natural states of matter: Any velocity once imparted to a moving body will be rigidly maintained as long as the external causes of retardation are removed!! Galileo’s statement is formulated by Newton into the 1st law of motion (Law of Inertia): In the absence of external forc ...
CHAPTER 14 :OSCILLATIONS One mark
... 3. What is the SI unit of frequency? 4. Give the relation between period and frequency of periodic motion. 5. What is the mean position(or equilibrium position) of an oscillating body? 6. Define the phase of particle in oscillatory motion. 7. What is the net external force acting on the body at its ...
... 3. What is the SI unit of frequency? 4. Give the relation between period and frequency of periodic motion. 5. What is the mean position(or equilibrium position) of an oscillating body? 6. Define the phase of particle in oscillatory motion. 7. What is the net external force acting on the body at its ...
Chapter 2
... But the instant he did that, the supporting beam broke and the basket, together with the poor prince, came crashing to the ground. What had happened was this. The King, who was very wicked, also happened to have had Physics 101 (no connection between the two), and he had originally designed the bea ...
... But the instant he did that, the supporting beam broke and the basket, together with the poor prince, came crashing to the ground. What had happened was this. The King, who was very wicked, also happened to have had Physics 101 (no connection between the two), and he had originally designed the bea ...
6.67 x 10 -11 m 3 /(kg s 2 )
... So what is happening • The monkey and the bullet are accelerating at the same speed downwards • g = 9.8 m/s2 = acceleration due to gravity • Objects fall faster by 9.8 m/s with every second • Even though the bullet has a velocity in the horizontal direction, it is also moving downwards in the verti ...
... So what is happening • The monkey and the bullet are accelerating at the same speed downwards • g = 9.8 m/s2 = acceleration due to gravity • Objects fall faster by 9.8 m/s with every second • Even though the bullet has a velocity in the horizontal direction, it is also moving downwards in the verti ...
CP Review Sheet Newton`s Laws
... 1. An apple that has a mass of 0.10 kg has the same mass wherever it is. The amount of matter that makes up the apple (depends on, does not depend on) the location of the apple. It has the same resistance to acceleration wherever it is – its inertia everywhere is (the same, different). The weight of ...
... 1. An apple that has a mass of 0.10 kg has the same mass wherever it is. The amount of matter that makes up the apple (depends on, does not depend on) the location of the apple. It has the same resistance to acceleration wherever it is – its inertia everywhere is (the same, different). The weight of ...
