Deck 3: How Things Move: Galileo Asks the Right Questions

A) It would fall, but much more slowly than a rock dropped on the moon.
B) It would rise.
C) It would fall at the same rate a rock falls when dropped on the moon.
D) It would remain suspended at the point of release.
E) It would turn into a giant pumpkin.

A) a car while it is rounding a corner at constant [or steady] speed
B) a car while it is moving at unchanging speed up a straight [or steady] incline
C) a car going over the crest of a rounded hill at a constant speed
D) a car starting up from rest
E) actually all of these cars are accelerating

A) four times as fast.
B) 12 times as fast.
C) eight times as fast.
D) 16 times as fast.
E) twice as fast.

A) Larger elliptical orbits.
B) Parabolas, like a thrown rock.
C) Straight line with an acceleration of 10 m/sec².
D) Straight line with no acceleration.
E) They would continue in their present orbits, since they already have no force on them.

A) 40 km/hr.
B) 24 km/hr.
C) 16 km/hr.
D) 32 km/hr.
E) None of the above.

A) using a flash camera to photograph the position of a ball at several equally- spaced times as the ball falls.
B) throwing an object horizontally from some distance above the ground, and measuring the time for it to hit the ground as compared with an object that is simply dropped from the same distance above the ground.
C) dropping an object to the floor from various heights, and measuring the time of fall.
D) dropping an object from several meters high, and measuring its position at the end of each second.
E) dropping an object to the floor from various heights, and observing the sound of the object hitting the floor.

A) of gravity.
B) the ether slows it down to a stop.
C) its natural motion is to come to rest.
D) of friction.
E) of its inertia.

A) An auto moving along a straight (or steady) upward incline at constant speed.
B) An auto rounding a curve at constant speed.
C) Both of the above.
D) None of the above.

A) Both of them say the force of friction slows it to a stop.
B) Both of them say that this is just the natural motion of the book.
C) Aristotle says the force of friction slows it to a stop, but Galileo says this is just the natural motion of the book.
D) They agree that physics books can make you crazy and it's best not to think about them.
E) Aristotle says this is just the natural motion of the book, but Galileo says the force of friction slows it to a stop.

A) 9 meters.
B) 8 meters.
C) 4 meters.
D) 16 meters.
E) 12 meters.

A) 32 m.
B) 64 m.
C) 16 m.
D) 24 m.
E) None of the above.

A) A car rounding a curve at a steady 80 km/hr
B) A car slowing down while moving along a straight line
C) Both of the above.
D) A car moving up a straight hill [a hill whose "slope" is unchanging] at a steady 80 km/hr, when the car is midway up the hill
E) All of the above.

A) A stone falling straight downward.
B) A book coming to rest as it slides along the floor.
C) Both of the above.
D) Neither of the above.

A) it is accelerated.
B) its speed is changing.
C) the direction of its velocity is downward.
D) All of the above.
E) None of the above.

A) 8 m
B) 12 m
C) 16 m
D) 32 m
E) 24 m

A) 64 m/s.
B) 16 m/s.
C) 48 m/s.
D) 32 m/s.
E) None of the above.

A) Nuclear processes operating in the central core of the moon.
B) It is the natural motion of every object to keep moving by itself.
C) Earth's gravity keeps it moving.
D) The sun's gravity keeps it moving.
E) It actually is slowing down, and will come to rest in a few thousand more years.

A) 15 m
B) 20 m
C) 9 m
D) 6 m
E) 12 m

A) 36 m/s
B) 24 m/s
C) 20 m/s
D) 40 m/s
E) 18 m/s

A) 12 m
B) 6 m
C) 3 m
D) 18 m
E) 9 m

A) an acceleration that is larger for more massive objects.
B) the same constant [or unchanging] acceleration.
C) the same constant (or unchanging) speed.
D) the same constant [or unchanging] velocity.
E) zero acceleration.

A) of friction.
B) the ether slows it down to a stop.
C) its natural motion is to come to rest.
D) of gravity.
E) of its inertia.

A) they have different speeds and different velocities.
B) they both have the same speed and the same velocity.
C) they both have the same speed but different velocities.
D) they have different speeds, but the same velocity.
E) None of the above.

A) an unchanging speed and an unchanging velocity.
B) a changing speed and a changing velocity.
C) a changing speed and a constant velocity.
D) an unchanging speed and a changing velocity.

A) an unchanging velocity.
B) zero velocity.
C) a decreasing velocity.
D) an increasing velocity.
E) None of the above.

A) None.
B) Fire.
C) Acceleration.
D) The Olympic gods.
E) Gravity.

A) Arrow A.
B) Arrow B.
C) Arrow C.
D) Arrow D.
E) Arrow E.

A) 16 m/s
B) 12 m/s
C) 4 m/s
D) 8 m/s
E) None of the above.

A) of electrical attraction.
B) its natural motion is to fall.
C) of gravity.
D) of friction.
E) of its inertia.

A) its speed remains unchanged while its direction of motion changes.
B) its speed changes while its direction of motion remains unchanged.
C) it is acted upon by an external influence.
D) its speed and its direction of motion are both unchanging.
E) both answers B and D are correct.

A) is accelerated.
B) has a changing velocity.
C) Both of the above.
D) None of the above.

A) A stone falling straight downward.
B) A book coming to rest as it slides along the floor.
C) Both a stone falling straight downward and a sliding book coming to rest are natural motions.
D) Neither a stone falling straight downward nor a sliding book coming to rest are natural motions.

A) According to Newton's law of motion, their own acceleration keeps them moving.
B) According to Newton's law of gravity, the force of gravity keeps them moving.
C) According to the law of inertia, nothing is needed to keep them moving.
D) According to current theories about the creation of the universe, the big bang keeps them moving.
E) According to Newton's law of gravity, nothing is needed to keep them moving.

A) air resistance must be negligible.
B) the two objects must have the same weight.
C) Both of the above.
D) the two objects must have the same size.
E) actually, this principle has no limitations.

A) Galileo understood that no force is needed to keep an object moving in a circle at constant speed.
B) Galileo understood that "natural" (or unforced) motion occurs at constant velocity.
C) Galileo understood that a force is needed to keep an object moving at constant velocity.
D) Galileo understood that energy is always conserved in every physical process.
E) Galileo understood that the gravitational force acts between every pair of objects in the universe.

A) 10 m/s
B) 5 m/s
C) 6 m/s
D) 0
E) 3 m/s

A) be at rest.
B) either be at rest or have constant velocity.
C) be accelerated, with an unchanging acceleration.
D) eventually come to rest.
E) fall.

A) non- zero velocity but zero acceleration.
B) zero velocity and zero acceleration (in other words, no acceleration).
C) non- zero velocity and non- zero acceleration.
D) zero velocity but non- zero acceleration.
E) the heebie- jeebies.

A) A car rounding a curve at a steady 80 km/hr.
B) A car moving up a straight hill [a hill whose "slope" is unchanging] at a steady 80 km/hr, when the car is midway up the hill.
C) A car moving along a straight horizontal (level) line at a steady 80 km/hr.
D) A car slowing down while moving along a straight line.
E) Both answers C and D are correct.

A) 100 m/sec.
B) 5 m/sec.
C) 10 m/sec.
D) 50 m/sec.
E) impossible to determine from the given information.

A) In the direction of arrow B, in a straight line.
B) In the direction of arrow C, in a straight line.
C) In the direction of arrow A, in a straight line.
D) It would continue moving in the same circular path.
E) Initially in the direction of arrow A, but then curving around toward the direction of arrow B.

A) a constant [or unchanging] acceleration.
B) a decreasing acceleration.
C) an increasing acceleration.
D) zero acceleration.
E) None of the above.

A) A stone falling straight downward.
B) A book coming to rest as it slides along the floor.
C) Both a stone falling straight downward and a sliding book coming to rest are natural motions.
D) Neither a stone falling straight downward nor a sliding book coming to rest are natural motions.

A) an increasing speed.
B) a decreasing speed.
C) an unchanging speed.
D) zero speed.
E) None of the above.

A) Distance is proportional to the time.
B) Distance is inversely proportional to the square of the time.
C) Distance is proportional to the square of the time.
D) The path followed by the motion is parabolic.
E) The path followed by the motion is elliptical.

A) 2 km/hr.
B) 48 km/hr.
C) 16 km/hr.
D) 4 km/hr.
E) 32 km/hr.

A) Yes, because its direction of motion is changing.
B) Yes, because its speed is changing.
C) No, because its speed is unchanging.
D) No, because its direction of motion is unchanging.
E) No, for both reasons C and D.

A) the upper ball, which has a larger speed, passes the lower ball.
B) the lower ball, which has a larger acceleration, passes the upper ball.
C) the upper ball, which has a larger acceleration, passes the lower ball.
D) the lower ball, which has a larger speed, passes the upper ball.
E) neither ball passes the other ball during their motion.

A) In equal times, a car covers shorter and shorter distances.
B) A car covers equal distances in equal times.
C) A car takes longer and longer times to cover equal distances.
D) A car covers equal distances in shorter and shorter times.
E) None of the above.

A) Heavy objects fall significantly faster than light objects.
B) Neglecting the effects of air resistance, light objects fall faster than heavy objects.
C) Neglecting the effects of air resistance, heavy objects fall faster than light objects.
D) Neglecting the effects of air resistance, all objects fall at roughly the same speed.
E) All objects fall at roughly the same speed.

A) four times as far.
B) twice as far.
C) 12 times as far.
D) eight times as far.
E) 16 times as far.

A) Actually, it isn't moving.
B) solar energy
C) gravity
D) the energy of space
E) its inertia

A) 20 m/sec
B) 80 m/sec
C) 40 m/sec
D) 60 m/sec
E) 180 m/sec

A) Yes, by turning the steering wheel.
B) Yes, by both of the above methods.
C) Yes, by pressing on the brake.
D) No, because the only way to speed up is to press on the accelerator.
E) No, because of the way that we define the word "acceleration" in physics.

A) velocity.
B) speed.
C) acceleration.
D) position.
E) All of the above.

A) A stone falling straight downward.
B) A book coming to rest as it slides along the floor.
C) Both of the above.
D) Neither of the above.

A) the rock falls faster than the feather, and both speeds are the same as they would be on Earth.
B) the two fall at the same speed, but this speed is slower than a rock would fall on Earth.
C) the two fall at the same speed, and this speed is the same as the speed of a rock falling on Earth.
D) the rock falls faster than the feather, although both of them fall slower than they would on Earth.
E) they don't fall-- they remain suspended above the surface of the moon.

A) the two have different speeds and different velocities.
B) Mike turns into a hippopotamus.
C) the two have different speeds but the same velocities.
D) the two have the same speeds but different velocities.
E) the two have the same speeds and the same velocities.

A) neither ball is accelerated, and the upper ball is moving fastest.
B) both balls are accelerated, and the lower ball is moving fastest.
C) the lower ball is accelerated, but the upper ball is not accelerated.
D) both balls are accelerated, and the upper ball is moving fastest.
E) neither ball is accelerated, and the lower ball is moving fastest.

A) their speeds are different but their velocities are identical.
B) their speeds are identical and their velocities are identical.
C) theoretical physics predicts, surprisingly enough, that they will turn into giant frogs.
D) their speeds are different and their velocities are different.
E) their speeds are identical but their velocities are different.

A) A smooth ball slows down when rolling uphill, and speeds up when rolling downhill, so it should maintain an unchanging speed on a level surface.
B) Noting that the length of the year does not change, he concluded that Earth must maintain an unchanging speed when moving around the sun.
C) Using a telescope, he observed meteors and comets moving at unchanging velocity through outer space.
D) All of the above.
E) He didn't have direct evidence, but proposed the law of inertia only because of the known failures of Aristotelian physics.

A) 4.8 cm/s.
B) 6 cm/s.
C) 0.4 cm/s.
D) 1.2 cm/s.
E) 0.8 cm/s.

A) Yes, for example when a car is halfway up a straight hill [a hill whose slope, or angle with the horizontal, does not change] and moving a an unchanging speed.
B) Yes, for example when a car turns a corner while maintaining an unchanging speed.
C) Both of the above.
D) No, because the word "acceleration" means "a change in speed."
E) No, because the word "acceleration" means "speeding up."

A) 18 km/hr.
B) 24 km/hr.
C) 2 km/hr.
D) 12 km/hr.
E) 9 km/hr.

A) 16 m/s
B) 32 m/s
C) 8 m/s
D) 72 m/s
E) 24 m/s

A) The car is accelerated, because its speed is changing.
B) The car is not accelerated, because its speed is not changing.
C) The car is not accelerated, because its direction of motion is not changing.
D) The car is accelerated, because its direction of motion is changing.
E) The car is not accelerated, because neither its direction of motion nor its speed are changing.

A) a big cloud made of chocolate fudge.
B) air, but no force due to gravity.
C) both air and a force due to gravity.
D) no air, but there is a force due to gravity.
E) no air and no force [or pull] due to gravity.

A) its velocity is zero but its acceleration is not zero [i.e., it does have an acceleration].
B) its velocity and acceleration are both zero.
C) neither its velocity nor its acceleration are zero.
D) its acceleration is zero but its velocity is not zero.
E) it has the heebie- jeebies.

A) zero.
B) 20 m/s.
C) more than 20 m/s, but the precise answer cannot be found without further information.
D) less than 20 m/s, but the precise answer cannot be found without further information.
E) None of the above.

A) the law of force pairs.
B) Newton's law of motion.
C) Aristotle's principle of natural motion.
D) the law of inertia.
E) Galileo's law of falling.