A 1.90 kg solid, uniform ball of radius 0.200 m is released from rest at point...

A 1.50 kg hoop of radius 0.200 m is released from rest at point A in...

A 1.50 kg hoop of radius 0.200 m is released from rest at point A in the figure below, its center of gravity a distance of 1.90 m above the ground. The hoop rolls without slipping to the bottom of an incline and back up to point B where it is launched vertically into the air. The hoop then rises to its maximum height hmax at point C. HINT 1.90 m 0.450 m (a) At point B, find the hoop's...

A Brunswick bowling ball with mass M= 7kg and radius R=0.15m rolls from rest down a...

A Brunswick bowling ball with mass M= 7kg and radius R=0.15m rolls from rest down a ramp without slipping. The initial height of the incline is H= 2m. The moment of inertia of the ball is I=(2/5)MR2 What is the total kinetic energy of the bowling ball at the bottom of the incline? 684J 342J 235J 137J If the speed of the bowling ball at the bottom of the incline is V=5m/s, what is the rotational speed ω at the...

An 8.50-cm-diameter, 360 g solid sphere is released from rest at the top of a 1.90-m-long,...

An 8.50-cm-diameter, 360 g solid sphere is released from rest at the top of a 1.90-m-long, 15.0 ∘ incline. It rolls, without slipping, to the bottom. Part A What is the sphere's angular velocity at the bottom of the incline? Part B What fraction of its kinetic energy is rotational?

A uniform, solid disk of mass M=4 kg and radius R=2 m, starts from rest at...

A uniform, solid disk of mass M=4 kg and radius R=2 m, starts from rest at a height of h=10.00 m and rolls down a 30 degree slope as shown in the figure. a) Derive the moment of inertia of the disk. b) What is the linear speed of the ball when it leaves the incline? Assume the ball rolls without slipping.

A sphere of radius r0 = 22.0 cm and mass m = 1.20kg starts from rest...

A sphere of radius r0 = 22.0 cm and mass m = 1.20kg starts from rest and rolls without slipping down a 34.0 degree incline that is 12.0 m long. Part A: Calculate its translational speed when it reaches the bottom. (m/s) Part B: Calculate its rotational speed when it reaches the bottom. (rad/s) Part C: What is the ratio of translational to rotational kinetic energy at the bottom? (Ktr/Krot) Part D: Does your answer in part A depend on...

a ball of mass M and radius R start from rest at a height of 5.0...

a ball of mass M and radius R start from rest at a height of 5.0 m and rolls down a 20 degree slope as he fig below. what is the linear speed of the ball when it leaves the incline? assuming that the ball rolls without slipping B) a disk of M and radius R start from rest at a height of 5.0 m and rolls down a 20 degree slope as he fig below. what is the linear...

A sphere of radius r0 = 22.0 cm and mass m = 1.20kg starts from rest...

A sphere of radius r0 = 22.0 cm and mass m = 1.20kg starts from rest and rolls without slipping down a 38.0 degree incline that is 11.0 mm long. A. Calculate its translational speed when it reaches the bottom. B. Calculate its rotational speed when it reaches the bottom. C. What is the ratio of translational to rotational kinetic energy at the bottom? D. Does your answer in part A depend on mass or radius of the ball? E....

A hollow ball of mass 2.88 kg and radius 0.309 m sits at rest on top...

A hollow ball of mass 2.88 kg and radius 0.309 m sits at rest on top of a hill of height 6.88 m. The ball can either slide down the hill without rolling or roll down without slipping. What is the difference in the ball's speed (in m/s) at the bottom of the hill between these two scenarios?

A sphere of radius r0 = 23.0 cm and mass m = 1.20kg starts from rest...

A sphere of radius r0 = 23.0 cm and mass m = 1.20kg starts from rest and rolls without slipping down a 35.0 ∘ incline that is 13.0 m long. A. Calculate its translational speed when it reaches the bottom. B. Calculate its rotational speed when it reaches the bottom. C. What is the ratio of translational to rotational kinetic energy at the bottom?

A sphere of mass M, radius r, and rotational inertia I is released from rest at...

A sphere of mass M, radius r, and rotational inertia I is released from rest at the top of an inclined plane of height h as shown above. (diagram not shown) If the plane has friction so that the sphere rolls without slipping, what is the speed vcm of the center of mass at the bottom of the incline?