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... the resistance of an object to changes in its rotational motion. (rotating objects keep rotating, non-rotating objects tend to stay still) • The further the mass is located from the axis of rotation, the greater the rotational inertia. • Greater rotational inertia means more laziness per mass. ...
... the resistance of an object to changes in its rotational motion. (rotating objects keep rotating, non-rotating objects tend to stay still) • The further the mass is located from the axis of rotation, the greater the rotational inertia. • Greater rotational inertia means more laziness per mass. ...
Chapter 11 Test
... 1. Which of the following is not a factor in calculating momentum? a. mass c. acceleration b. direction d. speed 2. If you divide momentum by velocity, the result is the value of the object’s a. mass. c. energy. b. direction. d. speed. 3. Whenever an object is standing still, the value(s) that is/ar ...
... 1. Which of the following is not a factor in calculating momentum? a. mass c. acceleration b. direction d. speed 2. If you divide momentum by velocity, the result is the value of the object’s a. mass. c. energy. b. direction. d. speed. 3. Whenever an object is standing still, the value(s) that is/ar ...
1 Physics 20 10 Summer 2016 Richard In "chretsen Exam 2
... Wearing a seat belt causes the immense forces generated in collisions to be transferred to more sturdy parts of your body, resulting in bruising rather than disability. In one collision scenario, a 55 kg. person rides hi a car travelling at 29.1 m/s (which is about 65 mph). Upon hitting another vehi ...
... Wearing a seat belt causes the immense forces generated in collisions to be transferred to more sturdy parts of your body, resulting in bruising rather than disability. In one collision scenario, a 55 kg. person rides hi a car travelling at 29.1 m/s (which is about 65 mph). Upon hitting another vehi ...
Circular Motion - Ferris Wheel Analysis
... Wheel? Draw free-body diagrams for the passenger at both the highest and lowest points. Show the direction of the net acceleration off to the side of each of the free-body diagrams. 11. Translate each of the two free body diagrams into an algebraic expression based on Newton’s second law (ΣF = ma). ...
... Wheel? Draw free-body diagrams for the passenger at both the highest and lowest points. Show the direction of the net acceleration off to the side of each of the free-body diagrams. 11. Translate each of the two free body diagrams into an algebraic expression based on Newton’s second law (ΣF = ma). ...
1 - Siena College
... Wheel? Draw free-body diagrams for the passenger at both the highest and lowest points. Show the direction of the net acceleration off to the side of each of the free-body diagrams. 11. Translate each of the two free body diagrams into an algebraic expression based on Newton’s second law (F = ma). ...
... Wheel? Draw free-body diagrams for the passenger at both the highest and lowest points. Show the direction of the net acceleration off to the side of each of the free-body diagrams. 11. Translate each of the two free body diagrams into an algebraic expression based on Newton’s second law (F = ma). ...
UNIT 7 Lab
... path would the object follow? Watch the animation that shows an object acted on by a force perpendicular to the velocity. The blue arrow indicates the direction of the force. The red arrow indicates the direction of the velocity. e. Acceleration is the change in velocity over a period of time. If th ...
... path would the object follow? Watch the animation that shows an object acted on by a force perpendicular to the velocity. The blue arrow indicates the direction of the force. The red arrow indicates the direction of the velocity. e. Acceleration is the change in velocity over a period of time. If th ...
Chapter 4 Rotating Coordinate Systems and the Equations of Motion
... rotating with the planet and hence, because of the rotation, a frame of reference that is not inertial. It is necessary , therefore, to examine how the equations of motion must be altered to take this into account. The earth rotates with an angular velocity Ω which we will take, for our purposes to ...
... rotating with the planet and hence, because of the rotation, a frame of reference that is not inertial. It is necessary , therefore, to examine how the equations of motion must be altered to take this into account. The earth rotates with an angular velocity Ω which we will take, for our purposes to ...
Document
... Currently, the only way to achieve this is by traveling to an indoor, controlled environment rigged with complex sensors and having a system contained within measure the swing. Not only are these facilities relatively sparse, but they are prohibitively expensive to the average golfer. ...
... Currently, the only way to achieve this is by traveling to an indoor, controlled environment rigged with complex sensors and having a system contained within measure the swing. Not only are these facilities relatively sparse, but they are prohibitively expensive to the average golfer. ...
uniform circular motion
... since s/r is unitless, radians are not a physical unit, and do not need to balance like most units. ...
... since s/r is unitless, radians are not a physical unit, and do not need to balance like most units. ...
Physics Year Long Plan
... describe the difference between "physics work" and every day work describe the relationship between force, displacement and the angle at which the force is applied use the work equation to calculate work done on an object use the different equations to determine power, force, work, time, average vel ...
... describe the difference between "physics work" and every day work describe the relationship between force, displacement and the angle at which the force is applied use the work equation to calculate work done on an object use the different equations to determine power, force, work, time, average vel ...
