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- https://phys.libretexts.org/Courses/Muhlenberg_College/MC%3A_Physics_121_-_General_Physics_I/12%3A__Angular_Momentum/12.02%3A_Rolling_MotionIn rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular...In rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular variables multiplied by the radius of the object. In rolling motion with slipping, a kinetic friction force arises between the rolling object and the surface. Energy conservation can be used to analyze rolling motion since energy is conserved in rolling motion without slipping.
- https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_(OpenStax)/Book%3A_University_Physics_I_-_Mechanics_Sound_Oscillations_and_Waves_(OpenStax)/11%3A__Angular_Momentum/11.02%3A_Rolling_MotionIn rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular...In rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular variables multiplied by the radius of the object. In rolling motion with slipping, a kinetic friction force arises between the rolling object and the surface. Energy conservation can be used to analyze rolling motion since energy is conserved in rolling motion without slipping.
- https://phys.libretexts.org/Workbench/PH_245_Textbook_V2/04%3A_Module_3_-_Conservation_Laws/4.02%3A_Objective_3.b./4.2.03%3A_Rolling_MotionIn rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular...In rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular variables multiplied by the radius of the object. In rolling motion with slipping, a kinetic friction force arises between the rolling object and the surface. Energy conservation can be used to analyze rolling motion since energy is conserved in rolling motion without slipping.
- https://phys.libretexts.org/Courses/Joliet_Junior_College/Physics_201_-_Fall_2019v2/Book%3A_Custom_Physics_textbook_for_JJC/11%3A_Rotational_Kinematics_Angular_Momentum_and_Energy/11.19%3A_Rolling_MotionIn rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular...In rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular variables multiplied by the radius of the object. In rolling motion with slipping, a kinetic friction force arises between the rolling object and the surface. Energy conservation can be used to analyze rolling motion since energy is conserved in rolling motion without slipping.
- https://phys.libretexts.org/Bookshelves/Mathematical_Physics_and_Pedagogy/Pedagogy/The_Axis_of_Rotation_for_Rolling_MotionAnalysing and teaching about the actual axis of rotation for a rolling object.
- https://phys.libretexts.org/Courses/Georgia_State_University/GSU-TM-Physics_I_(2211)/10%3A_Momentum/10.08%3A_Rolling_MotionThe bottom of the slightly deformed tire is at rest with respect to the road surface for a measurable amount of time. (b) This image shows that the top of a rolling wheel appears blurred by its motion...The bottom of the slightly deformed tire is at rest with respect to the road surface for a measurable amount of time. (b) This image shows that the top of a rolling wheel appears blurred by its motion, but the bottom of the wheel is instantaneously at rest. (credit a: modification of work by Nelson Lourenço; credit b: modification of work by Colin Rose)
- https://phys.libretexts.org/Courses/Joliet_Junior_College/Physics_201_-_Fall_2019/Book%3A_Physics_(Boundless)/10%3A_Rotational_Kinematics_Angular_Momentum_and_Energy/10.08%3A__Angular_Momentum/Rolling_MotionIn rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular...In rolling motion without slipping, a static friction force is present between the rolling object and the surface. The linear velocity, acceleration, and distance of the center of mass are the angular variables multiplied by the radius of the object. In rolling motion with slipping, a kinetic friction force arises between the rolling object and the surface. Energy conservation can be used to analyze rolling motion since energy is conserved in rolling motion without slipping.
- https://phys.libretexts.org/Courses/Georgia_State_University/GSU-TM-Physics_I_(2211)/09%3A_Work_Power_and_Energy/9.16%3A_Rolling_MotionAssuming the fixed point is not the center of mass (or the assertion is proved trivially), then let’s call the distance from the center of mass to the fixed point “d.” The center of mass is follow...Assuming the fixed point is not the center of mass (or the assertion is proved trivially), then let’s call the distance from the center of mass to the fixed point “d.” The center of mass is following a circular path of radius d around the fixed point, which means we can relate the linear velocity of the center of mass to its angular velocity around the fixed point:
