Vectors: Motion and Forces in Two Dimensions
... on the bullet. Consistent with Newton's third law of motion, the bullet pushes backwards upon the rifle. The acceleration of the recoiling rifle is ... a. greater than the acceleration of the bullet. b. smaller than the acceleration of the bullet. c. the same size as the acceleration of the bullet. ...
... on the bullet. Consistent with Newton's third law of motion, the bullet pushes backwards upon the rifle. The acceleration of the recoiling rifle is ... a. greater than the acceleration of the bullet. b. smaller than the acceleration of the bullet. c. the same size as the acceleration of the bullet. ...
Chapter 10 (Read Please)
... Angular Position, final We can associate the angle q with the entire rigid object as well as with an individual particle. Remember every particle on the object rotates through the same angle. The angular position of the rigid object is the angle q between the reference line on the object and the ...
... Angular Position, final We can associate the angle q with the entire rigid object as well as with an individual particle. Remember every particle on the object rotates through the same angle. The angular position of the rigid object is the angle q between the reference line on the object and the ...
Momentum - HRSBSTAFF Home Page
... force acts on an object, its velocity is constant. Its mass will not change. Therefore, if no force acts on an object, momentum is constant. Momentum is ...
... force acts on an object, its velocity is constant. Its mass will not change. Therefore, if no force acts on an object, momentum is constant. Momentum is ...
Monday, April 14, 2008
... The above condition is sufficient for a point-like object to be at its translational equilibrium. However for an object with size this is not sufficient. One more condition is needed. What is it? Let’s consider two forces equal in magnitude but in opposite direction acting on a rigid object as shown ...
... The above condition is sufficient for a point-like object to be at its translational equilibrium. However for an object with size this is not sufficient. One more condition is needed. What is it? Let’s consider two forces equal in magnitude but in opposite direction acting on a rigid object as shown ...
Summary of Chapters 1-3 Equations of motion for a uniformly accelerating object
... the gravity force pulling the mass down the ramp? As you slowly put the mass on the ramp, the ramp compresses & stretches along the ramp as gravity tries to slide the mass down the ramp. When you let go, the ramp has stretched enough to push on the mass with EXACTLY the right amount of force up the ...
... the gravity force pulling the mass down the ramp? As you slowly put the mass on the ramp, the ramp compresses & stretches along the ramp as gravity tries to slide the mass down the ramp. When you let go, the ramp has stretched enough to push on the mass with EXACTLY the right amount of force up the ...
ppt
... Galileo’s experiment A piece of wooden moulding or scantling, about 12 cubits [about 7 m] long, half a cubit [about 30 cm] wide and three finger-breadths [about 5 cm] thick, was taken; on its edge was cut a channel a little more than one finger in breadth; having made this groove very straight, smo ...
... Galileo’s experiment A piece of wooden moulding or scantling, about 12 cubits [about 7 m] long, half a cubit [about 30 cm] wide and three finger-breadths [about 5 cm] thick, was taken; on its edge was cut a channel a little more than one finger in breadth; having made this groove very straight, smo ...
Summary of Chapters 1-3 Equations of motion for a uniformly acclerating object
... the gravity force pulling the mass down the ramp? As you slowly put the mass on the ramp, the ramp compresses & stretches along the ramp as gravity tries to slide the mass down the ramp. When you let go, the ramp has stretched enough to push on the mass with EXACTLY the right amount of force up the ...
... the gravity force pulling the mass down the ramp? As you slowly put the mass on the ramp, the ramp compresses & stretches along the ramp as gravity tries to slide the mass down the ramp. When you let go, the ramp has stretched enough to push on the mass with EXACTLY the right amount of force up the ...
Dynamics 1
... Recognize the significance of Newton’s second law of motion and use it to solve motion ...
... Recognize the significance of Newton’s second law of motion and use it to solve motion ...
Determining the Net Force
... 11. During which time interval(s), if any, are there no forces acting upon the object? List all that apply. 12. During which time interval(s), if any, are the forces acting upon the object balanced.? List all that apply. 13. During which time interval(s), if any, is there a net force acting upon the ...
... 11. During which time interval(s), if any, are there no forces acting upon the object? List all that apply. 12. During which time interval(s), if any, are the forces acting upon the object balanced.? List all that apply. 13. During which time interval(s), if any, is there a net force acting upon the ...
Chapter 4 Forces and Newton’s Laws of Motion continued
... 4.3 Applications Newton’s Laws (Normal Forces) A block with a weight of 15 N sits on a table. It is pushed down with a force of 11 N or pulled up with a force of 11 N. Calculate the normal force in each ...
... 4.3 Applications Newton’s Laws (Normal Forces) A block with a weight of 15 N sits on a table. It is pushed down with a force of 11 N or pulled up with a force of 11 N. Calculate the normal force in each ...
CfE Advanced Higher Physics – Unit 1 – Rotational Motion
... Torque is a vector quantity. The direction of the torque vector is at right angles to the plane containing both r and F and lies along the axis of rotation. (In the example shown in the diagram torque, T, points out of the page). A tangential force acting on the rim of an object will cause the objec ...
... Torque is a vector quantity. The direction of the torque vector is at right angles to the plane containing both r and F and lies along the axis of rotation. (In the example shown in the diagram torque, T, points out of the page). A tangential force acting on the rim of an object will cause the objec ...