Momentum
... Impulse • Momentum can change. Most often, the mass of an object remains the same, while the velocity changes. • Dp = mDv • Dv acceleration a = Dv/t Dv=at • Dp = mDv becomes Dp = m x a x t • Dp = Force x time = Ft F • This is called Impulse – I = Ft ...
... Impulse • Momentum can change. Most often, the mass of an object remains the same, while the velocity changes. • Dp = mDv • Dv acceleration a = Dv/t Dv=at • Dp = mDv becomes Dp = m x a x t • Dp = Force x time = Ft F • This is called Impulse – I = Ft ...
Vectoring it up – The basic of Vectors and Physics
... or slow it down. In the real world objects that have a greater mass will require more energy to move (referred to as inertia). The greater the object’s mass, the more force it takes to change its motion. Imagine two spaceships in space, one big and one small. The only thing surrounding these spacesh ...
... or slow it down. In the real world objects that have a greater mass will require more energy to move (referred to as inertia). The greater the object’s mass, the more force it takes to change its motion. Imagine two spaceships in space, one big and one small. The only thing surrounding these spacesh ...
2 Mechanics
... 2.1.2 Explain the difference between instantaneous and average values of speed, velocity and acceleration. 2.1.3 Outline the conditions under which the equations for uniformly accelerated motion may be applied. 2.1.4 Identify the acceleration of a body falling in a vacuum near the Earth’s surface wi ...
... 2.1.2 Explain the difference between instantaneous and average values of speed, velocity and acceleration. 2.1.3 Outline the conditions under which the equations for uniformly accelerated motion may be applied. 2.1.4 Identify the acceleration of a body falling in a vacuum near the Earth’s surface wi ...
Producing RHS of Acceleration Eq.
... Use Cartesian generalized coordinates Formulate the velocity analysis problem Formulate the acceleration analysis problem ...
... Use Cartesian generalized coordinates Formulate the velocity analysis problem Formulate the acceleration analysis problem ...
Document
... and at 2 at some later time t t 2, then we say the change in displacement is r r2 r1 . Likewise, the elapsed time or time interval is t t 2 t1 . Similarly, the average acceleration is a v v2 v1 ...
... and at 2 at some later time t t 2, then we say the change in displacement is r r2 r1 . Likewise, the elapsed time or time interval is t t 2 t1 . Similarly, the average acceleration is a v v2 v1 ...
Circular Motion
... A Nonexistent Force According to Newton’s first law, you will continue moving with the same velocity unless there is a net force acting on you. The passenger in the car would continue to move straight ahead if it were not for the force of the door acting in the direction of the acceleration. The so- ...
... A Nonexistent Force According to Newton’s first law, you will continue moving with the same velocity unless there is a net force acting on you. The passenger in the car would continue to move straight ahead if it were not for the force of the door acting in the direction of the acceleration. The so- ...
pp\momentum - Dr. Robert MacKay
... Conservation of Momentum Collisions Explosions Elastic Collisions ...
... Conservation of Momentum Collisions Explosions Elastic Collisions ...
