Deck 2: Gravitation and the Motion of the Planets

A) propose a new experiment
B) take a formal vote at a recognized international scientific conference
C) modify existing theory
D) make predictions

A) followed patterns that could be described logically.
B) could be controlled by the thoughts and actions of humans.
C) were at the mercy of gods and spirits, and the behavior of these objects depended on their whims.
D) behaved chaotically, and their future behavior was totally unpredictable.

A) make an observation or do an experiment
B) analyze results
C) determine consistence with recognized authorities
D) choose the simplest existing theory

A) Copernicus.
B) Pythagoras.
C) Aristotle.
D) Ptolemy.

A) leading scientists in the world believe that it is wrong.
B) it disagrees with the accepted theory at the time of the proposal.
C) it appears to defy logic and logical reasoning.
D) it is in conflict with the results of just one reliable and repeatable observation.

A) belief that a theory accepted by leading scientists is correct
B) rejection of new scientific results when they disagree with the presently accepted theory
C) automatic rejection of a theory when new results disagree with its predictions
D) testing of predictions from a scientific theory or theoretical model

A) observations must be discarded.
B) theory must be modified.
C) the observations and the theory should both be retained.
D) theory must be discarded.

A) They uncovered the scientific writings of the Babylonians.
B) They invented a crude telescope.
C) They attempted to make mathematical models of physical phenomena.
D) Through trade routes, they had been exposed to the philosophy of the ancient orient.

A) agree with and build on previous theories but need not explain all observations because some of the observations may be erroneous.
B) predict new and different experiments that will extend the scope of the theoretical understanding but need not explain all the previous observations because no theory is expected to explain everything completely.
C) explain all previous reliable observations in a consistent manner but need not suggest new tests for the theory because a theory should be complete in itself.
D) explain all known reliable observations and predict new experiments and observations.

A) observation, faith, and acceptance.
B) rejection of all observations that disagree with theory.
C) logical derivation entirely from fundamental principles.
D) observation, logic, and skepticism.

A) discovering by observation the absolute truth about limited areas of science and are therefore slowly building up the correct view of the universe.
B) slowly amassing a vast bank of observations of nature that at some time in the future will be assembled into the correct description of the universe.
C) formulating hypotheses or models that describe the present observations of nature and that predict possible further tests for these models.
D) developing a theoretical view of the universe that incorporates all previous ideas and beliefs as part of an overall philosophy.

A) observations should be classified for future reference and the theory retained as the best explanation of the phenomenon.
B) observations must be discarded.
C) theory must be discarded.
D) theory must be modified to account for the observations, and if this is not possible, then the theory must be discarded.

A) they agree with what we find in experiments and observations.
B) results from experiments can be adjusted to agree with carefully constructed theoretical ideals.
C) they agree with the wisdom of the ancients.
D) they are so good and our faith in them is so strong that we never need to test them against observations.

A) it is possible, in principle, to disprove it by observation.
B) it is possible, in principle, to disprove it by logical argument.
C) it must be mathematically simple.
D) it must be mathematically complex.

A) triangles do not exist.
B) natural phenomena are wonderful to watch but cannot be described by mathematics.
C) the Sun is at the center of the planetary system.
D) natural phenomena can be described mathematically.

A) Plato.
B) Aristotle.
C) Newton.
D) Einstein.

A) can be independently and repeatedly checked by observation.
B) has been developed by a scientist with a solid reputation, such as Albert Einstein or Sir Isaac Newton.
C) has obtained the stamp of approval of an internationally renowned scientific body, such as the Royal Society of London or the International Astronomical Union.
D) accounts for a full range of historical observations, even though recent observations cast doubt on it.

A) the universe is governed by regular laws.
B) the Sun is the center of the solar system.
C) Earth is only one of hundreds of planets scattered throughout the galaxy.
D) gravitation keeps the planets in their orbits.

A) discard the observation as erroneous.
B) modify his hypothesis.
C) wait until someone develops an adequate explanation before announcing his observation.
D) reject those observations that do not agree with the theory.

A) it began with observations made over a century ago.
B) it began with theoretical calculations rather than observations.
C) the observations that began the investigation completely disproved the currently accepted model, thus leaving the theorists with no structure to build on.
D) the original theory was an outgrowth of an entirely unrelated area of philosophy.

A) Mercury, Venus, Mars, Jupiter, and Neptune.
B) Saturn, Venus, Mars, Mercury, and Jupiter.
C) Jupiter, Mercury, Mars, Uranus, and Venus.
D) Venus, Jupiter, Saturn, Mars, and Pluto.

A) field theory
B) astrology
C) cosmology
D) astronomy

A) apparent westward motion of the planet (and the Sun, the Moon, and stars) across the sky due to the rotation of Earth.
B) motion of the planet away from Earth during part of its orbit.
C) slow eastward motion of the planet from night to night compared to the background stars.
D) slow westward motion of the planet from night to night compared to the background stars.

A) retrograde motion.
B) precession.
C) rising (if in the east) or setting (if in the west).
D) direct motion.

A) east to west because of the rotation of Earth
B) east to west because of the motion of the planet along its orbit
C) west to east because of the motion of Earth along its orbit
D) west to east because of the motion of the planet along its orbit

A) The theory with the longest history is the most likely explanation.
B) The theory requiring the least number of unproven assumptions is the most likely explanation.
C) The newest theory is most likely to be the correct one.
D) The theory requiring the largest number of assumptions is the most likely explanation.

A) it began with observations made over a century ago.
B) it began with theoretical calculations rather than observations.
C) the observations that began the investigation completely disproved the currently accepted model, thus leaving the theorists with no structure to build on.
D) the original theory was an outgrowth of an entirely unrelated area of philosophy.

A) the theory that is applicable to the greatest range of phenomena is more likely to be correct.
B) when two theories describe the same phenomena equally accurately, the theory with the greater complexity is more likely to be correct.
C) when two theories describe the same phenomena equally accurately, the simpler theory is more likely to be correct.
D) the theory that describes phenomena more accurately is more likely to be correct.

A) temporary reversal of the planet's normal east-to-west motion past the background stars as seen from Earth.
B) apparent motion of a planet's moon in the opposite direction to the motion of the planet itself during half of each orbit of the moon around the planet.
C) temporary reversal of a planet's direction of spin about its axis of rotation.
D) temporary reversal of the planet's normal west-to-east motion past the background stars as seen from Earth.

A) pole star represented the center of the universe about which Earth and all other objects revolved.
B) Milky Way represented the observable universe, and its center was the center of the universe.
C) Sun was at the center of the universe.
D) Earth was at the center of the universe.

A) slow westward motion of the planet from night to night compared to the background stars.
B) apparent westward motion of the planet (and the Sun, the Moon, and stars) across the sky due to the rotation of Earth.
C) motion of the planet directly toward or away from Earth in certain parts of the planet's orbit.
D) slow eastward motion of the planet from night to night compared to the background stars.

A) the center of the galaxy.
B) a point midway between Earth and the Sun.
C) the Sun's center.
D) close to Earth's center.

A) rising (if in the east) or setting (if in the west).
B) direct motion.
C) precession.
D) retrograde motion.

A) 4.
B) 5.
C) 7.
D) 8.

A) A world body such as the United Nations must decree that the theory is correct.
B) The theory must be accepted by the vast majority of the population of Earth.
C) The theory must make predictions that are verifiable by observation or measurement.
D) The theory must be accepted by the vast majority of the scientific community.

A) bright nighttime object.
B) astrological sign.
C) wanderer.
D) nontwinkling star.

A) west to east relative to the background stars.
B) east to west relative to the background stars.
C) east to west relative to objects on the person's horizon.
D) west to east relative to objects on the person's horizon.

A) Archimedes.
B) Alexander.
C) Ptolemy.
D) Zorba.

A) regular patterns with general eastward motion interrupted by periods of westward motion.
B) regular and uniform eastward motion.
C) general eastward motion but with occasional stationary periods with no motion at all.
D) regular patterns with general westward motion interrupted by periods of eastward motion.

A) Earth-centered, with the Sun, the Moon, and the planets moving in ellipses in the sky.
B) Sun-centered, with elliptical planetary orbits.
C) Sun-centered, with the planets moving in circles around it.
D) Earth-centered, with planetary orbits composed of deferents and epicycles.

A) Mercury
B) Mars
C) the Moon
D) Jupiter

A) apparent motion of the planet away from Earth.
B) movement northward away from the ecliptic plane.
C) movement from west to east.
D) movement from east to west.

A) rise in the west and set in the east.
B) move westward with respect to the stars.
C) move at the same rate as the stars.
D) move eastward with respect to the stars.

A) planet's orbit is inclined at an angle to Earth's orbit.
B) planet's orbit is elliptical.
C) Sun is moving.
D) Earth is moving.

A) only the inner planets: Mercury and Venus.
B) only the outer planets: Mars and beyond.
C) all the planets.
D) all the planets and the Moon.

A) circle centered on Earth about which the center of the smaller circular motion moves.
B) off-center point in the planetary system occupied by Earth.
C) focus of the ellipse that is the orbit of the planet around Earth.
D) small circle through which the planet moves as the center of this circle orbits Earth.

A) westward motion against the star background.
B) westward motion with respect to the foreground on Earth.
C) eastward motion with respect to the Moon.
D) eastward motion against the star background.

A) always above the ecliptic.
B) always below the ecliptic.
C) sometimes above and sometimes below the ecliptic.
D) always on the ecliptic.

A) stationary, with no motion against the stars.
B) exactly perpendicular to the equator.
C) eastward.
D) westward.

A) sundial.
B) geocentric model for the solar system.
C) heliocentric model for the solar system.
D) method to measure Earth's radius.

A) no
B) yes, but only from the inner planets: Mercury and Venus
C) yes, but only from the outer planets: Mars and beyond
D) yes, from any of the planets

A) with varying speeds in elliptical orbits around Earth.
B) at constant speeds in circular orbits around Earth.
C) in circular epicycles around the Sun, while the Sun moves in a circular orbit around Earth.
D) in circular epicycles, while the centers of the epicycles move in circular orbits around Earth.

A) Mars
B) Venus
C) the Sun
D) Pluto

A) 180°
B) It can be any angle.
C) 0°
D) 90°

A) rotation of Earth on its axis.
B) revolution of Earth around the Sun.
C) motion of the Sun through the Galaxy.
D) motion of the stars around the galactic center.

A) Polish.
B) Greek.
C) Italian.
D) Egyptian.

A) origination of the idea of a geocentric (Earth-centered) cosmology, which was later developed by Aristarchus.
B) derivation of a model for the solar system in which the planets move around the Sun in circular orbits.
C) derivation of the model for the solar system in which the planets move around Earth in elliptical orbits, moving fastest when closest to Earth.
D) derivation of a model for the solar system in which the planets moved in epicycles and the epicycles orbited Earth.

A) religious, placing mankind at the center of creation.
B) religious, relegating Earth to an inferior position outside the perfect celestial realm.
C) based on observations.
D) based on the mathematics of the Pythagoreans.

A) setting of the planet in the west to any observer, caused by Earth rotation
B) eastward apparent motion with respect to the stars
C) southward motion of the planet as it moves away from the northern sky
D) westward apparent motion with respect to the stars

A) Venus
B) Earth
C) the Sun
D) Mars

A) deferent
B) celestial equator
C) ecliptic
D) epicycle

A) magnetism.
B) gravitation.
C) electrical forces.
D) no underlying physical theory.

A) Ptolemy's Almagest.
B) Plato's Republic.
C) Aristotle's Metaphysics.
D) Galileo's Dialogue Concerning the Two Chief World Systems.

A) Earth was at the center of the system.
B) the orbits were circular rather than elliptical.
C) it failed to take precession into account.
D) it failed to take retrograde motion into account.

A) a few days to a few weeks
B) a few weeks to a few months
C) a few days to a few months
D) a few weeks to a few years

A) epicycle
B) ecliptic
C) deferent
D) celestial equator

A) The planets actually stop and reverse direction in their orbits.
B) The planets move not in uniform circular motion about the Sun but rather in circular orbits (epicycles) about points which themselves move about the Sun in circular orbits.
C) Retrograde motion is an apparent motion of other planets, which we observe only because we are viewing their motion from Earth, itself in motion around the Sun.
D) Retrograde motion is an apparent motion caused by the precession of Earth's rotation axis.

A) develop a comprehensive model for a Sun-centered solar system.
B) use a telescope to observe the sky at night.
C) use ellipses to describe the orbits of the planets.
D) describe planetary orbits using the force of gravity.

A) There is no specific time in the orbit when the planet is closest to Earth.
B) during retrograde motion, westward
C) during direct motion, eastward
D) when the planet is crossing the deferent

A) at varying distances from Earth, sometimes closer and sometimes farther away than the average distance.
B) farther away from Earth than average.
C) closer to Earth than average.
D) always at the same distance from Earth because the planet orbits Earth in a circle in this model.

A) Kepler.
B) Copernicus.
C) Erathosthenes.
D) Ptolemy.

A) Mercury, Venus, Mars, Jupiter, and Saturn.
B) Mercury, Venus, Mars, Jupiter, and Uranus.
C) Jupiter, Venus, Neptune, Mars, and Saturn.
D) Mars, Neptune, Jupiter, Mercury, and Venus.

A) distance of the center of the epicycle from the center of Earth
B) small circle about which a planet moves while the center of the circle moves around Earth
C) distance of offset between the center of Earth and the center of a planet's orbit
D) large circle (orbit) that carries the planet around Earth while the planet itself is moving in a smaller circle

A) observations by spacecraft proved that all planets orbit the Sun.
B) the invention of the telescope provided observations that were in better agreement with a heliocentric model.
C) Isaac Newton was able to derive all planetary motion from one universal law of gravity.
D) the heliocentric model is conceptually simpler.

A) fact that a planet's speed in its orbit is fastest when it is closest to the Sun.
B) pattern of alternating conjunctions and oppositions.
C) pattern of alternating direct and retrograde motion.
D) general motion of all objects toward the west in the sky each day.

A) detailed multivolume account of a heliocentric cosmology produced by ancient Greek astronomers.
B) collection of ancient data and predictions of positions of the Sun, the Moon, and the planets, compiled by Ptolemy.
C) Renaissance book describing in detail the development of a heliocentric universe, with elliptical orbits, the law of equal areas, and the harmonic law.
D) ancient book describing the construction of Stonehenge.

A) small circle about which a planet moves while the center of this circle moves around Earth
B) large circle (orbit) that carries the planet around Earth while the planet itself is moving in a smaller circle
C) complete cycle of planetary motions after which the motions repeat themselves (almost) exactly
D) length of time from when the planet is farthest from Earth to the next time it is farthest from Earth

A) elliptical path along which a planet moves around the Sun.
B) circular path (around the Sun) along which the center of a planet's epicycle moves.
C) circular path (around Earth) along which the center of a planet's epicycle moves.
D) circular path along which a planet moves while the center of the path moves in a circle around Earth.

A) part of the planet's orbit when it appears to move "backward" (i.e., westward) in the sky.
B) off-center point in the planetary system occupied by Earth.
C) small circle about which the planet moves as the center of the circle orbits Earth.
D) circle about which each planet's epicycle center moves.