Use the position equation given below, where s represents the height of the object (in feet), v0 represents the initial velocity of the object (in feet per second), s0 represents the initial height of the object (in feet), and t represents the time (in seconds), as the model for the problem. s = −16t2 + v0t + s0 An aircraft flying at 400 feet over level terrain drops a supply package. (a) How long does it take until the supply package to strike the ground? (Round your answer to three decimal places.) t = sec (b) The aircraft is flying at 146 miles per hour. How far does the supply package travel horizontally during its descent? (Round your answer to one decimal place.) ft

Matt and his friends are enjoying an afternoon at a baseball game. A batter hits a towering homerun, and
Matt shouts, “Wow, that must have been 110 feet high!” The ball was 4 feet off the ground when the batter
hit it, and the ball came off the bat traveling vertically at 80 feet per second.

a. Model the ball’s height h (in feet) at time t (in seconds) using the projectile motion model h(t) = 16t2 + v0t + h0 where v0 is the projectile’s initial vertical velocity (in feet per second) and h0 is the projectile’s initial height (in feet). Use the model to write an equation based on Matt’s claim, and then determine whether Matt’s claim is correct.

b. Did the ball reach a height of 100 feet? Explain.

c. Let hmax be the ball’s maximum height. By setting the projectile motion model equal to hmax, show
how you can find hmax using the discriminant of the quadratic formula.

d. Find the time at which the ball reached its maximum height.