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please label and circle the answer A cart with a spring on the end of it...
A cart with a spring on the end of it is moving to the right in the positive x direction) on a frictionless air track as shown in the figure at the right. The initial position of the cart is arbitrary. It keeps going until it hits a wall, the spring compresses, and the cart bounces off the wall and moves in the opposite direction. Select all the graphs that could represent each of the following quantities as a function...
A cart of mass m rolls without friction on a level surface, and is attached to a light spring of constant k, the other end of which is attached to a wall. Take the initial position of the cart, where the spring is neither extended nor compressed, to be the origin x = 0 of a coordinate system where positive x values are to the right and positive vectors point to the right. The cart is pushed to the left...
A cart of mass m rolls without friction on a level surface, and is attached to a light spring of constant k, the other end of which is attached to a wall. Take the initial position of the cart, where the spring is neither extended nor compressed, to be the origin x = 0 of a coordinate system where positive x values are to the right and positive vectors point to the right. The cart is pushed to the left...
+ 0 A cart attached to a spring is given an initial push, Displacement, cm displacing it from its 4 A B equilibrium position. A 2 graph of displacement as a ус function of time for the 2 cart is shown at right. The -2-1 system has a total initial energy of 12 J and there is no friction. Five points are labeled A-E in the graph. For each labeled point, complete the bar chart below for the kinetic energy...
MacBook Air Inside one cart is a spring that is released Problem 2. Two that gives Cart B a velocity of 3 m/s to the right After: ?? carts, each of mass 2 kg, are at rest. to create an "explosion" Before: at rest B. gives After: 3 m/s dlaln your reasoning. (Spth er the explosion? Explain your re A. What is the mo 8. What is the momentum of Cart A after the explosion? Explain your reasoning. (Spt) C...
please answer all parts, thank you. 2. A cart on a frictionless track is attached on one side to a ideal spring. (The other side of the spring is fixed to the wall.) The cart has a mass of 1.20 kg. You compress the spring by 0.200 m and release the cart to oscillate at t = 0.00 s. The force needed to initially compress the spring is measured to be 10.0 N. (a) What is the angular frequency of...
A person exerts a 15-N force on a cart attached to a spring and holds the cart steady. The cart is displaced 0.060 m from its equilibrium position. When the person stops holding the cart, the system cart+spring undergoes simple harmonic motion. a) Determine the spring constant of the spring b) Determine the energy of the system c) Write expressions x(t), v(t), and a(t) for the motion of the cart d) Draw graphical representations of these expressions
A 2.00-kg object is free to slide on a horizontal surface. The object is attached to a spring of spring constant 300 N/m , and the other end of the spring is attached to a wall. The object is pulled in the direction away from the wall until the spring is stretched 50.0 mm from its relaxed position. The object is not released from rest, but is instead given an initial velocity of 2.50 m/s away from the wall. Ignore...
A cart at the end of a spring undergoes simple harmonic motion of amplitude A = 10 cm and frequency 5.0 Hz. Assume that the cart is at x=−A when t=0. a. Determine the period of vibration. b. Write an expression for the cart's position as a function of time. c. Determine the position of the cart at 0.050 s. d. Determine the position of the cart at 0.100 s.
i posted the firt question please answer the second pic A 2.0-kg block is released from rest at point A. The track is frictionless except for the rough portion between points B and C. The block travels down the track, hits a spring of force constant 1000 N/m, and compresses the spring 0.20 m from its equilibrium position before coming to rest momentarily. The mechanical energy of the system at point C is greater than the mechanical energy of the...