A 1.05 kg air-track glider is attached to each end of the track by two coil springs. It takes a horizontal force of 0.700 N to displace the glider to a new equilibrium position, x = 0.210 m. -X +X a) Find the effective spring constant of the system. Submit Answer Tries 0/6 b) The glider is now released from rest at x = 0.210 m. Find the maximum x-acceleration of the glider. Submit Answer Tries 0/6 c) Find the x-coordinate of the glider at time t = 0.470T, where T is the period of the oscillation. Submit Answer Tries 0/6 d) Find the kinetic energy of the glider at x = 0.00m. Submit Answer Tries 0/6

A 1.05 kg air-track glider is attached to each end of the track by two coil springs. It takes a horizontal force of 0.700 N to displace the glider to a new equilibrium position, x = 0.210 m. -X +X a) Find the effective spring constant of the system. Submit Answer Tries 0/6 b) The glider is now released from rest at x = 0.210 m. Find the maximum x-acceleration of the glider. Submit Answer Tries 0/6 c) Find the x-coordinate of the glider at time t = 0.470T, where T is the period of the oscillation. Submit Answer Tries 0/6 d) Find the kinetic energy of the glider at x = 0.00m. Submit Answer Tries 0/6

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

See similar textbooks

Similar questions

Pls help ASAP.
A 0.250 kg air-track glider is attached to each end of the track by two coil springs. It takes a horizontal force of 0.500 N to displace the glider to a new equilibrium position, x= 0.070 m. voooo 0 +X Find the effective spring constant of the system. The giider is now released from rest at x= 0.070 m. Find the maximum x-acceleration of the glider. Find the x-coordinate of the glider at time t= 0.350T, where T is the period of the oscillation. Find the kinetic energy of the glider at x=0.00 m. 1.75x10-² J You are correct. Your receipt no. is 157-1051 Previous Tries
can anyone step by step explain why answer is 0.2？
This, the length of the pendulum is 1.89 m. Now you start with the pendulum at 8.5 degrees with respect to the vertical, but rather than releasing it from rest, you give it a push downward. It swings to the other side, and reaches a maximum angle of 42.5 degrees with respect to the vertical. What must have been the initial speed of the pendulum just after you pushed it? 4.99 m/s 3.06 m/s 3.12 m/s 0.64 m/s
A pulley-and-cable assembly supports a block W and it requires a force at P for equilibrium. Since block W has a mass of 30kg (g=9.806), calculate the force of the spring CD and the magnitude of force P.
3. A simple pendulum is suspended from the ceiling by means of a string of length 1.60 m. Now you start with the pendulum at 16.6 degrees with respect to the vertical, but rather than releasing it from rest, you give it a push downward. It swings to the other side, and reaches a maximum angle of 55.4 degrees with respect to the vertical. What must have been the initial speed of the pendulum just after you pushed it? 4.78 m/s 3.50 m/s 3.68 m/s 1.14 m/s
7. Two bodies A and B in the figure shown are separated by a spring. Their motion down the incline is resisted by a force P = 200 lb. The coefficient of kinetic friction at A = 0.3 and kinetic friction at B = 0.1. Determine the force in the spring.
(b) Neglecting all resistive forces, determine the spring constant. N/m (c) Neglecting all resistive forces, find the speed of the projectile as it moves through the equilibrium position of the spring (where x = 0), as shown in Figure (b). m/s
a 7.5 kg block at rest on a tabletop is attached to a horizontal spring having a spring constant of 74.5 N/m. the spring is initially unstretched. a constant 75.0-N horizontal force is applied to the object causing the spring to stretch. determine the speed of the block in m/s after it has moved 0.75m from equilibrium if the surface between the block and the tabletop is if the coefficient of kinetic friction between block and tabletop is 0.20
Do it quickly
A 0.58-kg block attached to a spring with force constant 127 N/m is free to move on a frictionless, horizontal surface as in the figure below. The block is released from rest after the spring is stretched 0.13 m. = 0 F - 0 x- 0 (a) At that instant, find the force on the block. magnitude direction -Select-- v (b) At that instant, find its aceleration. magnitude m/s2 direction -Select-- v
Please Asap