practice

1. 
   [magnify]
   The following passages are excerpts from "The Long, Lonely Leap" by Captain Joseph W. Kittinger, Jr. USAF as they appeared in National Geographic magazine. It is the story of his record-setting, high altitude parachute jump from a helium balloon over New Mexico on 16 August 1960.

   An hour and thirty-one minutes after launch, my pressure altimeter halts at 103,300 feet. At ground control the radar altimeters also have stopped on readings of 102,800 feet, the figure that we later agree upon as the more reliable. It is 7 o'clock in the morning, and I have reached float altitude.

   At zero count I step into space. No wind whistles or billows my clothing. I have absolutely no sensation of the increasing speed with which I fall.

   Though my stabilization chute opens at 96,000 feet, I accelerate for 6,000 feet more before hitting a peak of 614 miles an hour, nine-tenths the speed of sound at my altitude. An Air Force camera on the gondola took this photograph when the cotton clouds still lay 80,000 feet below. At 21,000 feet they rushed up so chillingly that I had to remind myself they were vapor and not solid.

   Verify the speed claim of the author. (At this altitude g = 9.72 m/s².)
2. A basketball dropped from rest 1.00 m above the floor rebounds to a height of 0.67 m. Assuming the ball is not moving horizontally, calculate its velocity …
   1. before it hit the floor on the way down and
   2. just after it left the floor on the way up.
   If the ball is in contact with the floor for 0.10 s determine its acceleration …
   3. on the way down,
   4. while it is contact with the floor, and
   5. on the way up.
3. A diver jumps from a 3 m board with an initial upward velocity of 5.5 m/s. Determine …
   1. the time the diver was in the air,
   2. the maximum height to which she ascended, and
   3. her velocity on impact with the water.
4. Sketch the following graphs of motion for an object thrown straight upward.
   1. displacement-time,
   2. velocity-time, and
   3. acceleration-time

conceptual

1. A ball is thrown straight up over level ground. State the direction of the velocity and acceleration vectors …
   1. on the way up,
   2. at the highest point, and
   3. on the way down.

numerical

1. Whole body reaction time is about three-tenths of a second. Would you have enough time to throw yourself clear of a brick falling from a point 3 m directly overhead if you saw it the moment it came loose?
2. A bullet leaves the muzzle of a 1.000 m long rifle with a velocity of 400.0 m/s when fired straight up. Determine the muzzle velocity when the rifle is fired straight down instead.
3. The terminal velocity of a skydiver is 55 m/s (120 mph) at typical jump altitudes.
   1. Determine the minimum time and displacement needed to reach to reach this velocity for a skydiver starting from rest.
   2. Why are these values minimums?
4. In the early 2000s, three skydivers proposed attempts to break Joseph Kittinger's 1960 world record parachute jump: Michel Fournier of France, Cheryl Stearns of the United States, and Rodd Millner of Australia. All planned to jump from an altitude of 40 km (130,000 feet) -- 8 km (5 miles) higher than Captain Kittinger. With this additional distance, it is quite possible that one of them would have exceeded the speed of sound. Due to a series of technical and financial troubles, however, none of them have managed to get off the ground.
   1. At what altitude might one of these skydivers break through the sound barrier? Assume that the acceleration due to gravity is 9.70 m/s², the speed of sound is 300 m/s, and that air resistance is negligible.
   2. Captain Kittinger believed that air resistance was negligible down to about 27.5 km (90,000 feet). Assuming a continued acceleration of 9.72 m/s² after exceeding the speed of sound, determine a possible maximum speed during such a jump.
5. A baseball is thrown upward at 20 m/s. At what time is the ball …
   1. 10 m above the point at which it was released?
   2. 20 m above the point at which it was released?
   3. 30 m above the point at which it was released?
6. A stone is thrown upward from a point 72 m above the ground and is airborne for 6 s.
   1. Determine the initial velocity of the stone.
   2. At some later time the stone is moving downward at 12 m/s.
      1. When does this occur?
      2. Where does this occur?
7. Two acrobats are about to perform a stunt; one on a trampoline and another 5.0 m above on a platform. At the instant that the acrobat on the platform steps off, the acrobat on the trampoline is moving upward at 7.5 m/s.
   1. When do the two acrobats pass each other?
   2. At what height above the trampoline are they?
   3. What are their respective velocities?

investigative

1. You can determine a person's reaction time using a centimeter ruler. Find several volunteers and have them hold their open hand out so that you can drop a ruler between their thumb and fingers. Suspend the ruler vertically with the zero mark of the ruler at the same level as the top of your volunteer's open hand. Tell your volunteers to grab the ruler the instant you drop it. Release it without warning and record the position on the ruler where they grabbed it. (Take the reading from the top of their fingers.) Repeat this test a few times for each volunteer to obtain an average value. Record your results along with your volunteer's ages (or another demographic variable that you think may be relevant). Determine the relation, if any, between age and reaction time in your sample. (A list of demographic variables to test might include such things as gender, place of birth, hours spent playing video games, hours spent watching TV, number of siblings, whatever.)
2. How high should a domed baseball stadium be built if it is to accommodate even the highest pop fly? There are two ways to solve this problem …
   1. using the time a pop fly is in the air or
   2. using the speed of a batted ball.
   Use whichever method you find easiest.