A spring with constant k = 7 N/m hanging from the ceiling is placed at its lower end with an object of 1 N, which makes it remain in equilibrium. The weight is then pulled 0.7 m above the equilibrium position and released with no initial velocity. There is no damping force acting on the system. If x(t) represents the displacement of the weight, in meters, from the equilibrium point and taking upwards as the positive direction, an equation that describes the position of the weight as a function of time t (in seconds) is: If necessary, use the gravity constant g as g=9.8 m/s?. a) ¤(t) = 0.35 (etv68.6 + e=tv68.6 ot/68.6 -t/68.6 b) x(t) = 0.35 sen(t/68.6) c) æ(t) = 0.7 cos(t/68.6) 0) #(t) = 0.7 (etv®%o +etv888) et/68.6

(Please solve by hand)

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A spring with constant k = 7 N/m hanging from the ceiling is placed at its lower end with an object of 1 N, which makes it remain in equilibrium. The weight is then pulled 0.7 m above the equilibrium position and released with no initial velocity. There is no damping force acting on the system. If x(t) represents the displacement of the weight, in meters, from the equilibrium point and taking upwards as the positive direction, an equation that describes the position of the weight as a function of time t (in seconds) is: If necessary, use the gravity constant g as g=9.8 m/s?. etv68 a) x(t) = 0.35 ( 68.6 +e-tv68.6 b) x(t) = 0.35 sen(t/68.6) c) x(t) = 0.7 cos(t/68.6) d) æ(t) = 0.7 (etv68.6 tetv68.6