You have an oscillator made with a spring and a cart on an inclined plane. part...

1) a) A block of mass m slides down an inclined plane starting from rest. If...

1) a) A block of mass m slides down an inclined plane starting from rest. If the surface is inclined an angle theta above the horizontal, and the block reaches a speed V after covering a distance D along the incline, what is the coefficient of kinetic friction? b) at a distance D1 (still on the incline), the block comes to an instantaneous standstill against a spring with spring constant k. How far back up does the block? Why do...

A block of mass m = 3.3 kg is on an inclined plane with a coefficient...

A block of mass m = 3.3 kg is on an inclined plane with a coefficient of friction μ1 = 0.39, at an initial height h = 0.53 m above the ground. The plane is inclined at an angle θ = 44°. The block is then compressed against a spring a distance Δx = 0.13 m from its equilibrium point (the spring has a spring constant of k1 = 35 N/m) and released. At the bottom of the inclined plane...

A block of weight w = 25.0 N sits on a frictionless inclined plane, which makes...

A block of weight w = 25.0 N sits on a frictionless inclined plane, which makes an angle θ = 20.0 ∘ with respect to the horizontal, as shown in the figure. (Figure 1)A force of magnitude F = 8.55 N , applied parallel to the incline, is just sufficient to pull the block up the plane at constant speed. Part B What is Wg, the work done on the block by the force of gravity w⃗  as the block moves...

A block of weight w = 30.0 N sits on a frictionless inclined plane, which makes...

A block of weight w = 30.0 N sits on a frictionless inclined plane, which makes an angle θ = 33.0 ∘ with respect to the horizontal, as shown in the figure. (Figure 1)A force of magnitude F = 16.3 N , applied parallel to the incline, is just sufficient to pull the block up the plane at constant speed. PART A The block moves up an incline with constant speed. What is the total work WtotalWtotalW_total done on the...

A simple harmonic oscillator is made from a mass on a spring. If you start the...

A simple harmonic oscillator is made from a mass on a spring. If you start the mass oscillating by pulling the mass downward by a distance A and releasing it from rest, let us assume the maximum velocity it achieves during its oscillation is v. What would the maximum velocity be if you instead pulled the mass down by 2A then released it from rest?

Two blocks made of different materials, connected by a thin cord, slide down a plane ramp...

Two blocks made of different materials, connected by a thin cord, slide down a plane ramp inclined at an angle θθ to the horizontal, (Figure 1). The masses of the blocks are mAmA = mBmB = 6.5 kgkg , and the coefficients of friction are μAμAmu_A = 0.19 and μBμBmu_B = 0.31, the angle θθ = 32∘∘. Part A) Determine the acceleration of the blocks. Part B)Determine the tension in the cord.

Consider a simple harmonic oscillator made of a mass sliding on a frictionless surface, and attached...

Consider a simple harmonic oscillator made of a mass sliding on a frictionless surface, and attached to a massless linear spring. Which of the following statements are true? (If A and E are, and the others are not, enter TFFFT).      A) Doubling the mass will not change the period.      B) Doubling the amplitude will halve the frequency.      C) Quadrupling the spring constant will double the frequency.      D) Doubling the mass will double the frequency.      E)...

You are a medical consultant to a health technology company evaluating an inexpensive traction system for...

You are a medical consultant to a health technology company evaluating an inexpensive traction system for exerting a predictable force at the location of a patient’s leg injury. The device consists of a foot-strap connected to a weight by a rope that goes over a pulley. You are worried that the force exerted on the injury will change when the angle of the leg changes. As a first step in understanding the situation, you decide to model the portion of...

You land in a spring-loaded cart (k=144 kN/m) (m=500kg) which instantly launches you along a 3.5m...

You land in a spring-loaded cart (k=144 kN/m) (m=500kg) which instantly launches you along a 3.5m track (Mu-(0.1,0.05) that then enters a loop that has a height of 10m at the top. a. If your speed at the top of the loop is 12 m/s what is the initial compression of the spring? (constant friction) b. If the loop continues around and then launches off a 3.5m long, 30 degrees incline, how high will it fly? I use these to...

PART 1: This time we have a crate of mass 26.5 kg on an inclined surface,...

PART 1: This time we have a crate of mass 26.5 kg on an inclined surface, with a coefficient of kinetic friction 0.168. Instead of pushing on the crate, you let it slide down due to gravity. What must the angle of the incline be, in order for the crate to slide with an acceleration of 4.44 m/s^2? A) 21.6 degrees B) 50.4 degrees C) 28.8 degrees D) 36.0 degrees PART 2: Different situation now. You re out in space,...