1. When an object is in free fall near the surface of the Earth, the only force acting on it is the force of gravity (ignoring wind and air resistance), which produces a constant acceleration of-32 ft/s. Therefore, the acceleration function of an object in freefall is a(t)=-32 ft/s. Suppose an object is thrown straight upward with an initial velocity of 50 ft/s from an initial height of 128 feet. a) Since acceleration is the derivative of velocity, you can find the velocity function by taking the anti-derivative of the acceleration function. Find the velocity function ") this way and use the initial value v (0) = 50 to solve for the constant term. b) Since velocity is the derivative of position, you can find the position function by taking the s(1) this way and use the anti-derivative of the velocity function. Find the position function initial value $ (0)=128 to solve for the constant term. c) How long will it take for the object to hit the ground (to the nearest hundredth of a second)? (Hint: you will need to use the quadratic formula).

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1. When an object is in free fall near the surface of the Earth, the only force acting on it is the force of gravity (ignoring wind and air resistance), which produces a constant acceleration of -32 ft/s. Therefore, the acceleration function of an object in freefall is a(t)=-32 ft/s. Suppose an object is thrown straight upward with an initial velocity of 50 ft/s from an initial height of 128 feet. a) Since acceleration is the derivative of velocity, you can find the velocity function by taking the anti-derivative of the acceleration function. Find the velocity function ") this way and use the initial value (0)= 50 to solve for the constant term. b) Since velocity is the derivative of position, you can find the position function by taking the anti-derivative of the velocity function. Find the position function $C) this way and use the s (0)=128 to solve for the constant term. initial value c) How long will it take for the object to hit the ground (to the nearest hundredth of a second)? (Hint: you will need to use the quadratic formula).