the period of an object attached to a spring oscillating on an inclined plane(no friction) depends...

A 2 kg object is attached to a spring and is oscillating on a horizontal surface....

A 2 kg object is attached to a spring and is oscillating on a horizontal surface. When the object has a speed of 10 m/s, the spring is stretched 2 m. The spring constant is 10 N/m. Neglect friction. Find the maximum speed of the object. What is the maximum stretch in the spring? What is the object's speed when the spring is stretched 1 m? What is the stretch in the spring when the object's speed is 5 m/s?

3. Derive the expression for the period of an oscillating mass attached to a spring using...

3. Derive the expression for the period of an oscillating mass attached to a spring using Newton’s second law of motion and Hooke’s law.

When an object is on an inclined plane, the normal forcer exerted the inclined plane. What...

When an object is on an inclined plane, the normal forcer exerted the inclined plane. What is the reasoning behind this?

Jae dropped an object from an inclined plane. The angle of the inclined plane with respect...

Jae dropped an object from an inclined plane. The angle of the inclined plane with respect to the horizontal direction is 30 degrees and the distance from where the object was dropped to the surface of the Earth in a vertical direction is 100 meters. Assuming that the object is a solid sphere and it is going to move with a certain angular velocity as it moves down the inclined plane and there is no frictional force that we need...

An object with a mass m = 45.6 g is attached to a spring with a...

An object with a mass m = 45.6 g is attached to a spring with a force constant k = 12.3 N/m and released from rest when the spring is stretched 36.2 cm. If it is oscillating on a horizontal frictionless surface, determine the velocity of the mass when it is halfway to the equilibrium position.

Motion of an oscillating mass [0.75 kg] attached to the spring is described by the equation...

Motion of an oscillating mass [0.75 kg] attached to the spring is described by the equation below: (??) = 7.4 (????) ?????? [(4.16 ?????? ?? ) ?? ? 2.42] Find: a. Amplitude b. Frequency c. Time Period d. Spring constant e. Velocity at the mean position f. Potential energy g. at the extreme position.

If a block of mass 10 kg slides down an inclined plane having an angle of...

If a block of mass 10 kg slides down an inclined plane having an angle of 30 degrees above the horizon,at the end of the inclined plane there is a frictionless surface on the end of it lies a spring having spring constant 500N/m.There is friction on the inclined plane,Find the coefficient of kinetic friction of the inclined plane. when the block reaches the spring,it compresses it by 0.40m Let the block start from rest and the height be 20...

A box with 10 kg of mass slides down an inclined plane that is 1.7 m...

A box with 10 kg of mass slides down an inclined plane that is 1.7 m high and 3.5 m long. Due to friction the box reaches 3.0 m/s at the bottom of the inclined plane. Beyond the inclined plane lies a spring with 650 N/m constant. It is fixed at its right end. The level ground between the incline and the spring has no friction The box compressed the spring, got pushed back towards the incline by the spring....

A box with 11 kg of mass slides down an inclined plane that is 2.0 m...

A box with 11 kg of mass slides down an inclined plane that is 2.0 m high and 3.5 m long. Due to friction the box reaches 3.3 m/s at the bottom of the inclined plane. Beyond the inclined plane lies a spring with 650 N/m constant. It is fixed at its right end. The level ground between the incline and the spring has no friction The box compressed the spring, got pushed back towards the incline by the spring....

Consider an inclined plane at an angle of 40.0°, with a kinetic coefficient of friction of...

Consider an inclined plane at an angle of 40.0°, with a kinetic coefficient of friction of 0.350 and a static coefficient of friction of 0.450. A block with mass of 50.0 kg is on the incline and initially at rest. A force of 535 N, parallel to the incline, pushes the block a distance of 10.0 m up the incline. Do the following: a) Determine the speed of the object at the end of this displacement using Newton’s Laws of...