PhysicsMCExamReview-SPG2015
... object that is equal in magnitude but opposite in direction is a statement of a. kinematics b. Newton’s second law c. Newton’s third law d. net force 23. The acceleration of an object is directly proportional to the net force on it and inversely proportional to it’s mass is a statement of a. kinemat ...
... object that is equal in magnitude but opposite in direction is a statement of a. kinematics b. Newton’s second law c. Newton’s third law d. net force 23. The acceleration of an object is directly proportional to the net force on it and inversely proportional to it’s mass is a statement of a. kinemat ...
Phys 111 Fall 2009
... relative motion in 1 and 2D The Relative velocity VECTOR equation (use of subscripts) Boat example (simple 1D) Difference between going and heading ...
... relative motion in 1 and 2D The Relative velocity VECTOR equation (use of subscripts) Boat example (simple 1D) Difference between going and heading ...
Word
... momentum as the product of mass × velocity force as rate of change of momentum conservation of momentum when objects interact Revision Notes: Momentum; Newton’s Laws of motion Summary Diagrams: Conservation of momentum; Collisions from different viewpoints; Examples of collisions; Momentum and force ...
... momentum as the product of mass × velocity force as rate of change of momentum conservation of momentum when objects interact Revision Notes: Momentum; Newton’s Laws of motion Summary Diagrams: Conservation of momentum; Collisions from different viewpoints; Examples of collisions; Momentum and force ...
Lecture07-09
... forces on it are N (up) and mg (down), so N must be greater than mg in order to give the net upward force! Follow-up: What is the normal force if the elevator is in free fall downward? ...
... forces on it are N (up) and mg (down), so N must be greater than mg in order to give the net upward force! Follow-up: What is the normal force if the elevator is in free fall downward? ...
Chapter 10 (Read Please)
... There is an analogy between the kinetic energies associated with linear motion (K = ½ mv 2) and the kinetic energy associated with rotational motion (KR= ½ I2). Rotational kinetic energy is not a new type of energy, the form is different because it is applied to a rotating object. The units of rota ...
... There is an analogy between the kinetic energies associated with linear motion (K = ½ mv 2) and the kinetic energy associated with rotational motion (KR= ½ I2). Rotational kinetic energy is not a new type of energy, the form is different because it is applied to a rotating object. The units of rota ...
