At the instant the displacement of a 2.00 kg object relative to the origin is ?...

At the instant the displacement of a 2.00 kg object relative to the origin is =...

At the instant the displacement of a 2.00 kg object relative to the origin is = (2.00 m) + (4.00 m) - (3.00 m) , its velocity is = - (1.70 m/s) + (9.57 m/s) + (2.99 m/s) and it is subject to a force = (5.04 N) - (9.13 N) + (7.38 N) . Find the acceleration of the object ((a), (b) and (c) for , and components respectively), the angular momentum of the object about the origin ((d),...

A 4.71 kg mass moving in space according to v= (6.00t2 - t)i + (15.0t2)j +(t3...

A 4.71 kg mass moving in space according to v= (6.00t2 - t)i + (15.0t2)j +(t3 + 3.14t)k (relative to the origin), with v in meter/second and t in seconds. At t= 1.57s (a) what are the magnitude and direction of the force acting on the mass (b) what is the angle between the acceleration and velocity vector (c) what is the average velocity? (d) What is the mass angular momentum relative to the origin? (e) What is the torque...

A 3.00-kg particle starts from the origin at time zero. Its velocity as a function of...

A 3.00-kg particle starts from the origin at time zero. Its velocity as a function of time is given by v = (3t^2) i+ (2t) j where v is in meters per second and t is in seconds. (a) Find its position at t = 1s. (b) What is its acceleration at t = 1s ? (c) What is the net force exerted on the particle at t = 1s ?   (d) What is the net torque about the origin...

A 11.00 kg particle starts from the origin at time zero. Its velocity as a function...

A 11.00 kg particle starts from the origin at time zero. Its velocity as a function of time is given by v with arrow = 9t2î + 3tĵ where v with arrow is in meters per second and t is in seconds. (Use the following as necessary: t.) (a) Find its position as a function of time. (b) Describe its motion qualitatively. (c) Find its acceleration as a function of time. (d) Find the net force exerted on the particle...

A 3.65 kg particle with velocity v→=(8.97m/s)î-(4.43m/s)ĵ is at x = 7.38 m, y = 5.02...

A 3.65 kg particle with velocity v→=(8.97m/s)î-(4.43m/s)ĵ is at x = 7.38 m, y = 5.02 m. It is pulled by a 2.09 N force in the negative x direction. About the origin, what are (a) the particle's angular momentum, (b) the torque acting on the particle, and (c) the rate at which the angular momentum is changing?

A 14.00 kg particle starts from the origin at time zero. Its velocity as a function...

A 14.00 kg particle starts from the origin at time zero. Its velocity as a function of time is given by v with arrow = 9t2î + 4tĵ where v with arrow is in meters per second and t is in seconds. (Use the following as necessary: t.) (a) Find its position as a function of time. r =________ (c) Find its acceleration as a function of time. a=_______m/s^2 ( (d) Find the net force exerted on the particle as...

An ice skater with a moment of inertia of 0.390 kg*m2 is spinning at 6.00 rev/s...

An ice skater with a moment of inertia of 0.390 kg*m2 is spinning at 6.00 rev/s a. What is the angular velocity of the ice skater in rad/s? b. What is the angular momentum of the ice skater at this angular velocity c. He reduces his rate of spin (angular velocity) by extending his arms and increasing his moment of inertia. Find the value of his moment of inertia if his angular velocity drops to 1.70 rev/s d. Suppose instead...

A small object with mass 4.10 kg moves counterclockwise with constant speed 1.35 rad/s in a...

A small object with mass 4.10 kg moves counterclockwise with constant speed 1.35 rad/s in a circle of radius 3.05 m centered at the origin. It starts at the point with position vector 3.05î m. Then it undergoes an angular displacement of 8.65 rad. (a) What is its new position vector? m (b) In what quadrant is the particle located and what angle does its position vector make with the positive x-axis? Second  at ??° (c) What is its velocity? m/s...

A 3.00-kg rod that is 1.40 m long is free to rotate in a vertical plane...

A 3.00-kg rod that is 1.40 m long is free to rotate in a vertical plane about an axle that runs through the rod's center, is perpendicular to the rod's length, and runs parallel to the floor. A 1.00-kg block is attached to one end of the rod, and a 2.00-kg block is attached to the other end. At some instant, the rod makes an angle of 37.0 ? with the horizontal so that the blocks are in the positions...

A 3.00-kg rod that is 2.60 m long is free to rotate in a vertical plane...

A 3.00-kg rod that is 2.60 m long is free to rotate in a vertical plane about an axle that runs through the rod's center, is perpendicular to the rod's length, and runs parallel to the floor. A 1.00-kg block is attached to one end of the rod, and a 2.00-kg block is attached to the other end. At some instant, the rod makes an angle of 31.0 ? with the horizontal so that the blocks are in the positions...