Uniform Circular Motion
... NO. There is no longer a force pulling it towards the center. It will follow the path of the velocity vector, which is tangent to the circle. The ball with continue on a straight path. ...
... NO. There is no longer a force pulling it towards the center. It will follow the path of the velocity vector, which is tangent to the circle. The ball with continue on a straight path. ...
Chapter 13 Notes
... a. Average speed is how far an object moves in a given amount of time. Average Speed = Distance Time b. Motion is always measured in relation to some location called point of reference. c. Velocity describes the speed and direction of an object. Lesson 2: What are forces? Pushes and Pulls a. A for ...
... a. Average speed is how far an object moves in a given amount of time. Average Speed = Distance Time b. Motion is always measured in relation to some location called point of reference. c. Velocity describes the speed and direction of an object. Lesson 2: What are forces? Pushes and Pulls a. A for ...
Test 2 Review Test 2 Review (15-16)
... test. Please come to class Thursday with questions for Mr. Matthews. (1) State whether the following are True (T) or False (F). __________ Inertia is a measure of how difficult it is to change the velocity of an object. __________ A sled slides down a hill and onto flat ground. Once on flat ground, ...
... test. Please come to class Thursday with questions for Mr. Matthews. (1) State whether the following are True (T) or False (F). __________ Inertia is a measure of how difficult it is to change the velocity of an object. __________ A sled slides down a hill and onto flat ground. Once on flat ground, ...
laws of motion
... For object sliding on a smooth inclined plane • The acceleration depends on the inclination of the plane only. It does not depend on the mass. Objects of different masses slide on the inclined plane with the same acceleration. • The acceleration always points down-slope, independent of the directio ...
... For object sliding on a smooth inclined plane • The acceleration depends on the inclination of the plane only. It does not depend on the mass. Objects of different masses slide on the inclined plane with the same acceleration. • The acceleration always points down-slope, independent of the directio ...
Document
... The centrifugal force does not act on the body in motion; the only force acting on the body in motion is the centripetal force The centrifugal force acts on the source of the centripetal force to displace it radially from the center of the path Thus, in twirling a mass on a string, the centripetal f ...
... The centrifugal force does not act on the body in motion; the only force acting on the body in motion is the centripetal force The centrifugal force acts on the source of the centripetal force to displace it radially from the center of the path Thus, in twirling a mass on a string, the centripetal f ...
Short Answer
... 14. A pitcher releases a fastball that moves toward home plate. Other than the force exerted by the pitcher, what are two forces that act on the ball as it travels between the pitcher and home plate? How does each of these forces change the ball’s motion? Classify the forces acting on the ball as ba ...
... 14. A pitcher releases a fastball that moves toward home plate. Other than the force exerted by the pitcher, what are two forces that act on the ball as it travels between the pitcher and home plate? How does each of these forces change the ball’s motion? Classify the forces acting on the ball as ba ...
Newton`s 2nd Law of Motion
... remains constant and the mass decreases the acceleration increases, and 4) if the net force remains constant and the mass increases the acceleration decreases. It is also possible to show that if mass and force increase or decrease by the same factor, the acceleration will have no change as illustra ...
... remains constant and the mass decreases the acceleration increases, and 4) if the net force remains constant and the mass increases the acceleration decreases. It is also possible to show that if mass and force increase or decrease by the same factor, the acceleration will have no change as illustra ...
Motion - TeacherWeb
... Superman Leaps To the Top of a Building. . . . . . . • Let’s say the building has a height of 660 feet • His final velocity (V2) at the top is equal to 0 (cause he stopped to admire the view) • We don’t know his starting velocity (V1) or how long it took to get to the top. . . . • So – modifying th ...
... Superman Leaps To the Top of a Building. . . . . . . • Let’s say the building has a height of 660 feet • His final velocity (V2) at the top is equal to 0 (cause he stopped to admire the view) • We don’t know his starting velocity (V1) or how long it took to get to the top. . . . • So – modifying th ...
Circular Motion - Pat-Med Physics AP Exam Regents Exam
... Newton’s 2nd Law: The net force on a body is equal to the product of the mass of the body and the acceleration of the body. ...
... Newton’s 2nd Law: The net force on a body is equal to the product of the mass of the body and the acceleration of the body. ...
AP Physics: Air Resistance/Differential Practice
... and hence acting in the downward direction. Likewise, when the mass is moving downward the velocity (and so v) is positive. Therefore, the air resistance must also have a “-” in order to make sure that it’s negative and hence acting in the upward direction. ...
... and hence acting in the downward direction. Likewise, when the mass is moving downward the velocity (and so v) is positive. Therefore, the air resistance must also have a “-” in order to make sure that it’s negative and hence acting in the upward direction. ...
South Pasadena • Physics Name 5 · Applications of Forces Period
... Calculate the frequency (rev / t) and speed of an object (v = 2 π r f) in circular motion. Know why the velocity vector points in the direction of motion of an object, which is tangent to the circular path, and why the acceleration and force vectors point toward the center of the circular path. ...
... Calculate the frequency (rev / t) and speed of an object (v = 2 π r f) in circular motion. Know why the velocity vector points in the direction of motion of an object, which is tangent to the circular path, and why the acceleration and force vectors point toward the center of the circular path. ...
File
... (D) The direction of the frictional force acting on the book is in the same direction as the frictional force acting on the crate. (E) The Newton’s Third Law reaction force to the weight of the book is the normal force from the table ...
... (D) The direction of the frictional force acting on the book is in the same direction as the frictional force acting on the crate. (E) The Newton’s Third Law reaction force to the weight of the book is the normal force from the table ...
Class Set: Use your own paper! Forces and Laws of Motion A 80
... speed of 15 km/h relative to the truck in the direction opposite to the tuck’s motion. One observer is stationary on the side of the road and another observer is traveling in a car that is moving in the same direction as the truck but passing the truck at a faster speed. 12. What is the velocity of ...
... speed of 15 km/h relative to the truck in the direction opposite to the tuck’s motion. One observer is stationary on the side of the road and another observer is traveling in a car that is moving in the same direction as the truck but passing the truck at a faster speed. 12. What is the velocity of ...
G-force
g-force (with g from gravitational) is a measurement of the type of acceleration that causes weight. Despite the name, it is incorrect to consider g-force a fundamental force, as ""g-force"" (lower case character) is a type of acceleration that can be measured with an accelerometer. Since g-force accelerations indirectly produce weight, any g-force can be described as a ""weight per unit mass"" (see the synonym specific weight). When the g-force acceleration is produced by the surface of one object being pushed by the surface of another object, the reaction-force to this push produces an equal and opposite weight for every unit of an object's mass. The types of forces involved are transmitted through objects by interior mechanical stresses. The g-force acceleration (save for certain electromagnetic force influences) is the cause of an object's acceleration in relation to free-fall.The g-force acceleration experienced by an object is due to the vector sum of all non-gravitational and non-electromagnetic forces acting on an object's freedom to move. In practice, as noted, these are surface-contact forces between objects. Such forces cause stresses and strains on objects, since they must be transmitted from an object surface. Because of these strains, large g-forces may be destructive.Gravitation acting alone does not produce a g-force, even though g-forces are expressed in multiples of the acceleration of a standard gravity. Thus, the standard gravitational acceleration at the Earth's surface produces g-force only indirectly, as a result of resistance to it by mechanical forces. These mechanical forces actually produce the g-force acceleration on a mass. For example, the 1 g force on an object sitting on the Earth's surface is caused by mechanical force exerted in the upward direction by the ground, keeping the object from going into free-fall. The upward contact-force from the ground ensures that an object at rest on the Earth's surface is accelerating relative to the free-fall condition (Free fall is the path that the object would follow when falling freely toward the Earth's center). Stress inside the object is ensured from the fact that the ground contact forces are transmitted only from the point of contact with the ground.Objects allowed to free-fall in an inertial trajectory under the influence of gravitation-only, feel no g-force acceleration, a condition known as zero-g (which means zero g-force). This is demonstrated by the ""zero-g"" conditions inside a freely falling elevator falling toward the Earth's center (in vacuum), or (to good approximation) conditions inside a spacecraft in Earth orbit. These are examples of coordinate acceleration (a change in velocity) without a sensation of weight. The experience of no g-force (zero-g), however it is produced, is synonymous with weightlessness.In the absence of gravitational fields, or in directions at right angles to them, proper and coordinate accelerations are the same, and any coordinate acceleration must be produced by a corresponding g-force acceleration. An example here is a rocket in free space, in which simple changes in velocity are produced by the engines, and produce g-forces on the rocket and passengers.