Reminders: * 1st HW due Sep 16 * 1st Midterm moved to Oct 4
... • An object tends to remain at rest, or, if moving, to continue moving at constant speed in a straight line (1st Law). Objects tend to resist changes in motion (inertia) – mass measures this. • (2nd Law) When there is a net force on an object, it will accelerate: a = Fnet/m, a is in the same directi ...
... • An object tends to remain at rest, or, if moving, to continue moving at constant speed in a straight line (1st Law). Objects tend to resist changes in motion (inertia) – mass measures this. • (2nd Law) When there is a net force on an object, it will accelerate: a = Fnet/m, a is in the same directi ...
Slide 1
... • An object is in translational equilibrium if the net force acting on it is zero. • Connected objects have the same acceleration. • The force required to move an object of mass m in a circle of radius r is: ...
... • An object is in translational equilibrium if the net force acting on it is zero. • Connected objects have the same acceleration. • The force required to move an object of mass m in a circle of radius r is: ...
forces_newton1_phy1151
... Draw a picture of the situation. Show the object—the system—and everything in the environment that touches the system. Ropes, springs, and surfaces are all parts of the environment. Draw a closed curve around the system. Only the object is inside the curve; everything else is outside. Locate e ...
... Draw a picture of the situation. Show the object—the system—and everything in the environment that touches the system. Ropes, springs, and surfaces are all parts of the environment. Draw a closed curve around the system. Only the object is inside the curve; everything else is outside. Locate e ...
Answer Key Physics Study Guide A
... Falling objects in a vacuum. g=10m/s2. Be able to calculate velocity after a certain time in free-fall (v=gt) An object falls from rest. What is its speed after 5 seconds? gt = v 10x5 = 50 m/s …after 8 seconds? gt = v 10x8 = 80 m/s All projectiles (thrown objects) on earth accelerate DOWN (due to g ...
... Falling objects in a vacuum. g=10m/s2. Be able to calculate velocity after a certain time in free-fall (v=gt) An object falls from rest. What is its speed after 5 seconds? gt = v 10x5 = 50 m/s …after 8 seconds? gt = v 10x8 = 80 m/s All projectiles (thrown objects) on earth accelerate DOWN (due to g ...
Document
... Suppose you have a solid sphere sitting at rest. It has no kinetic energy at all—no motion. Now push on it with a linear force. It accelerates (in the direction of the force) to a non-zero linear velocity. Now it’s moving—it has kinetic energy: KT = (1/2)mv2 Where did that energy come from? It was t ...
... Suppose you have a solid sphere sitting at rest. It has no kinetic energy at all—no motion. Now push on it with a linear force. It accelerates (in the direction of the force) to a non-zero linear velocity. Now it’s moving—it has kinetic energy: KT = (1/2)mv2 Where did that energy come from? It was t ...
Circular Motion
... It is defined as the ratio of angular displacement to the time taken by the object to undergo the displacement. Angular acceleration It is defined as the ratio of change in angular velocity of the object to the time taken to undergo the change in angular velocity. ...
... It is defined as the ratio of angular displacement to the time taken by the object to undergo the displacement. Angular acceleration It is defined as the ratio of change in angular velocity of the object to the time taken to undergo the change in angular velocity. ...
Solutions to Period 3 Exercises
... about 3 x 108 miles to reach Mars. It moved at an average speed of 1.5 x 106 miles per day. How many days did it take to reach its destination? a) 400 days b) 365 days c) ...
... about 3 x 108 miles to reach Mars. It moved at an average speed of 1.5 x 106 miles per day. How many days did it take to reach its destination? a) 400 days b) 365 days c) ...
Why do things move? - USU Department of Physics
... times the rotational acceleration. τ = I.α • Or the rotational acceleration produced is equal to the τ torque divided by the moment of inertia of object. (α = I ). • Larger rotational inertia ‘I’ will result in lower acceleration. ‘I’ dictates how hard it is to change rotational velocity. Example: T ...
... times the rotational acceleration. τ = I.α • Or the rotational acceleration produced is equal to the τ torque divided by the moment of inertia of object. (α = I ). • Larger rotational inertia ‘I’ will result in lower acceleration. ‘I’ dictates how hard it is to change rotational velocity. Example: T ...
Free fall
In Newtonian physics, free fall is any motion of a body where its weight is the only force acting upon it. In the context of general relativity, where gravitation is reduced to a space-time curvature, a body in free fall has no force acting on it and it moves along a geodesic. The present article only concerns itself with free fall in the Newtonian domain.An object in the technical sense of free fall may not necessarily be falling down in the usual sense of the term. An object moving upwards would not normally be considered to be falling, but if it is subject to the force of gravity only, it is said to be in free fall. The moon is thus in free fall.In a uniform gravitational field, in the absence of any other forces, gravitation acts on each part of the body equally and this is weightlessness, a condition that also occurs when the gravitational field is zero (such as when far away from any gravitating body). A body in free fall experiences ""0 g"".The term ""free fall"" is often used more loosely than in the strict sense defined above. Thus, falling through an atmosphere without a deployed parachute, or lifting device, is also often referred to as free fall. The aerodynamic drag forces in such situations prevent them from producing full weightlessness, and thus a skydiver's ""free fall"" after reaching terminal velocity produces the sensation of the body's weight being supported on a cushion of air.