PES 1110 Fall 2013, Spendier Lecture 10/Page 1 Today:
... Reference frames in which Newtonian mechanics holds are called inertial reference frames or inertial frames. These are reference frames that move with constant velocity , including v = 0. We typically say that the ground is an inertial frame. But we know from last lecture that the earth’s rotation c ...
... Reference frames in which Newtonian mechanics holds are called inertial reference frames or inertial frames. These are reference frames that move with constant velocity , including v = 0. We typically say that the ground is an inertial frame. But we know from last lecture that the earth’s rotation c ...
Lecture 9
... net force per unit mass equals the acceleration, and is the vector sum of all forces [N kg-1] acting (actually each force is a vector) ...
... net force per unit mass equals the acceleration, and is the vector sum of all forces [N kg-1] acting (actually each force is a vector) ...
Presentation - ScienceScene
... walking, swimming, jumping, rocket motion, objects resting on a table, tug-world of- war. Realcontexts: Changing the direction--changing the direction of a billiard ball, bus turning a corner; changing the speed--car speeding up, a rolling ball slowing down, magnets changing the motion of objects, w ...
... walking, swimming, jumping, rocket motion, objects resting on a table, tug-world of- war. Realcontexts: Changing the direction--changing the direction of a billiard ball, bus turning a corner; changing the speed--car speeding up, a rolling ball slowing down, magnets changing the motion of objects, w ...
Forces
... Newton’s Second Law • The acceleration of an object is directly proportional to the net force acting on the object and inversely proportional to the object’s mass. ...
... Newton’s Second Law • The acceleration of an object is directly proportional to the net force acting on the object and inversely proportional to the object’s mass. ...
Biomechanics
... When a rotating body moves from one position to another, the angular distance through which it moves is equal to the length of the angular path. The angular displacement that a rotating body experiences is equal in magnitude to the angle between the initial and final position of the body. Angular mo ...
... When a rotating body moves from one position to another, the angular distance through which it moves is equal to the length of the angular path. The angular displacement that a rotating body experiences is equal in magnitude to the angle between the initial and final position of the body. Angular mo ...
Document
... Newton could not finish his theory mathematically so he put his papers in a drawer until he had developed __________________. This took him 20 years!! ...
... Newton could not finish his theory mathematically so he put his papers in a drawer until he had developed __________________. This took him 20 years!! ...
Section 6.2 Word
... Acceleration deals with a change in velocity (vector quantity thus magnitude and DIRECTION) divided by a change in time, thus something that is moving around in a circle at a constant speed has acceleration since the direction is changing. ...
... Acceleration deals with a change in velocity (vector quantity thus magnitude and DIRECTION) divided by a change in time, thus something that is moving around in a circle at a constant speed has acceleration since the direction is changing. ...
Newton`s 1st and 2nd Laws
... A ball is sitting motionless on the ground. Earth’s gravitational pull accelerates objects at 9.8m/s2. What do you know about the NET FORCE acting on the ball? ...
... A ball is sitting motionless on the ground. Earth’s gravitational pull accelerates objects at 9.8m/s2. What do you know about the NET FORCE acting on the ball? ...
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.