Review - WordPress.com
... Force is a vector (magnitude and direction). Forces cause an object to accelerate… ...
... Force is a vector (magnitude and direction). Forces cause an object to accelerate… ...
3 3 Newton`s Second Law
... acceleration varies directly as the force, and inversely as the mass. To really appreciate Newton’s Laws, it sometimes helps to see how they build on each other. The first law describes what will happen if there is no force, and the second law describes what will happen if there is a force. Let’s br ...
... acceleration varies directly as the force, and inversely as the mass. To really appreciate Newton’s Laws, it sometimes helps to see how they build on each other. The first law describes what will happen if there is no force, and the second law describes what will happen if there is a force. Let’s br ...
Chapter 5
... fluid does not have a constant acceleration. • To find acceleration at a point of time, we need to use Newton’s second law. ...
... fluid does not have a constant acceleration. • To find acceleration at a point of time, we need to use Newton’s second law. ...
Chapter 5 Work and Energy conclusion
... Energy can neither be created not destroyed, but can only be converted from one form to another. Heat energy is the kinetic or vibrational energy of molecules. The result of a non-conservative force is often to remove mechanical energy and transform it into heat. Examples of heat generation: sliding ...
... Energy can neither be created not destroyed, but can only be converted from one form to another. Heat energy is the kinetic or vibrational energy of molecules. The result of a non-conservative force is often to remove mechanical energy and transform it into heat. Examples of heat generation: sliding ...
ch6 momentum
... The time rate of change of momentum of an object is equal to the ____________ acting on the object Net Force ...
... The time rate of change of momentum of an object is equal to the ____________ acting on the object Net Force ...
Wednesday, June 25, 2008
... Angular Momentum of a Particle If you grab onto a pole while running, your body will rotate about the pole, gaining angular momentum. We’ve used the linear momentum to solve physical problems with linear motions, the angular momentum will do the same for rotational motions. Let’s consider a point-l ...
... Angular Momentum of a Particle If you grab onto a pole while running, your body will rotate about the pole, gaining angular momentum. We’ve used the linear momentum to solve physical problems with linear motions, the angular momentum will do the same for rotational motions. Let’s consider a point-l ...
Rotational Motion
... Sketch r and F with respect to the origin Determine the direction of the force with the right hand rule. Calculate the torque produced by this force. Verify that your direction agrees with your calculation. ...
... Sketch r and F with respect to the origin Determine the direction of the force with the right hand rule. Calculate the torque produced by this force. Verify that your direction agrees with your calculation. ...
Force - Eastside Physics
... between any two bodies in the universe • Newton’s Law of Universal Gravitation =every particle in the universe attracts every other particle with a force that is directly proportional to the product of their masses and inversely proportional to the square of the distance between them • F g = Gm1m2/r ...
... between any two bodies in the universe • Newton’s Law of Universal Gravitation =every particle in the universe attracts every other particle with a force that is directly proportional to the product of their masses and inversely proportional to the square of the distance between them • F g = Gm1m2/r ...
