ST

ST. PETERSBURG COLLEGE

APPROVED COURSE OUTLINE

AST 1003 THE SOLAR SYSTEM ___3__

Prefix Number Course Title Cr.Hrs.

A. Course Description:

Prerequisites: ENC 0020 and REA 0002 or EAP 1695 and MAT 0024. This course is a study of earth as a planet, the moon, and the sun, measurement of time, eclipses, planets and their satellites, comets, meteors, and various theories of the origin of the solar system. Consideration will be given to the historical development of the science and the basic principles of mechanics as applied to astronomy. (This course may not be taken for credit subsequent to receiving a grade of "C" or better in AST 1002.) 47 contact hours.

B. Major Learning Outcomes:

1. The student will acquire understanding of the history of astronomy and its relationship to other sciences.

2. The student will acquire understanding of the areas of research on the solar system of primary importance today.

3. The student will acquire understanding of the features of the various members of the solar system and the mechanical relationships between them.

4. The student will be able to use various simple astronomical instruments and understand their application to the field.

C. Course Objectives Stated in Performance Terms:

1. The student will acquire understanding of the history of astronomy and its relationship to other sciences by:

a. listing at least 8 astronomical concepts contributed by the ancient Greeks.

b. defining:

(1) Celestial sphere (9) retrograde motion

(2) Zenith (10) north and south celestial poles

(3) nadir (11) conjunction

(4) celestial horizon (12) quadrature

(5) ecliptic (13) elongation

(6) planet (14) sidereal period

(7) zodiac (15) synodic period

(8) constellation (16) conic section

(17) major and semi-major axis (38) equation of time

(18) eccentricity (39) standard time

(19) inertia (40) coriolis effect

(20) mass (41) great circle

(21) force (42) hour circle

(22) vector (43) meridian

(23) acceleration (44) equator latitude

(24) density (45) longitude

(25) weight (46) horizon

(26) equilibrium (47) celestial equator

(27) volume (48) celestial horizon

(28) reaction force (49) celestial meridian

(29) differential force (50) altitude

(30) neap tide (51) azimuth

(31) spring tide (52) right ascension

(32) hour angle (53) declination

(33) sidereal time (54) vernal equinox

(34) sidereal day (55) autumnal equinox

(35) solar day (56) winter solstice

(36) apparent solar time (57) summer solstice

(37) mean solar time

c. describing the contributions of Aristotle, Hipparchus, Ptolemy, Eratosthenes.

d. describing the phenomenon of retrograde motion and explaining it on the basis of current theory.

e. describing the contributions of Copernicus to the hellocentric hypothesis.

f. describing the concept of relative motion.

g. solving problems dealing with synodic and sidereal periods.

h. describing Brahe's contributions to astronomy and how they led to Kepler's theory.

i. describing Kepler's contributions to astronomy and stating and using Kepler's laws in appropriate situations.

j. describing Galileo's contributions to physics and astronomy.

k. stating the three laws of Newton and also his law of Universal Gravitation and being able to apply these laws to the solution of simple problems.

l. solving simple vector addition problems.

m. stating the distinction between mass and weight and calculating the weight of an object given its mass and the local gravitational acceleration.

n. demonstrating how the mass of the earth can be obtained by the application of Newton's laws.

o. finding the center of mass of a two body system.

p. stating Newton's corrections to the three laws of Kepler (in particular (M₁ + M₂ ) p² = a³).

q. calculating the masses of other planets by application of the corrected third law of Kepler.

r. describing the orbits of satellites in terms of their initial burnout speed with respect to apogee and perigee.

s. stating the n-body problem.

t. describing the shape of the earth and stating the effect of rotation on the shape.

u. describing the effects of the moon on earth tides.

v. describing the precessional motion of the earth.

w. stating the importance of the Foucault pendulum.

x. contrasting the horizontal system of coordinates to the equator system.

y. describing how observations of stars depends upon location of the observer and what is necessary for a star to be circumpolar.

z. describing the methods for demonstrating that the earth revolves.

aa. relating the seasons to the location of the sun on the celestial sphere.

bb. calculating distance to earth's horizon from various elevations above sea level.

cc. relating the hour angle of the real sun (apparent solar time) to the hour angle of the mean sun (mean solar time).

dd. converting from angular measure to time measure (360° = 24 hr., etc.).

ee. describing how time depends upon longitude and calculating time differences given longitude differences.

ff. describing the need for standard time zones and explaining how to obtain this from mean time and solar time.

2. The student will demonstrate understanding of the area of research on the solar system of primary importance today by:

a. defining frequency and wave length and relating these terms to the speed of light.

b. explaining qualitatively, the inverse square laws.

c. relating the wavelengths of electromagnetic radiation to the various regions of classification.

d. finding the energy of a photon given its wavelength or frequency.

e. explaining the laws of reflection, refraction, and dispersion.

f. defining continuous spectrum, absorption spectrum, emission spectrum.

g. explaining the value of spectral analysis.

h. explaining the Doppler effect and its implications.

i. defining the term blackbody radiator and applying the Wien Law and the Stefan-Boltzmann law to simple problems.

j. defining proton, neutron, electron, and atom.

k. explaining, on the basis of the Bohr atomic theory, emission and absorption spectra.

l. defining ionization energy.

m. Additional objectives to be covered if time permits:

(1) stating the principle of relativity.

(2) listing the two postulates of special relativity.

(3) distinguishing between special and general relativity.

(4) contrasting the Galilean viewpoint with Einstein's as far as transformations of length, time and mass.

(5) calculating length, mass, and time in appropriate situations by using the Lorentz transformation.

(6) explaining the Einstein relation between mass and energy.

(7) stating and explaining the principle of equivalence.

(8) defining or describing the terms: geodesic, space time, curvature, gravitational waves.

3. The student will demonstrate understanding of the features of the various members of the solar system and the mechanical relationships between them by:

a. indicating the gross features of the earth and moon.

b. indicating the various atmospheric zones of the earth and the composition of these zones.

c. describing the magnetic field of the earth and defining bowshock.

d. defining Van Allen layer, metamorphic rock, igneous rock, sedimentary rock, plate tectonics.

e. indicating what has been learned about the internal structure of the earth.

f. indicating the temperature variations of the moon.

g. defining maria and indicating the various types of lunar features (mountain ranges, craters, etc.).

h. defining sidereal and synodic month.

i. explaining the delay in moon rise.

j. indicating approximate time by noting position and phase of the moon.

k. giving the distance, mass, and size of the moon.

l. explaining the geometry of lunar and solar eclipses and indicating the time periods involved.

m. defining total, annular, penumbral and partial eclipses and occultation and transit.

n. classifying the planets as to density and location, i.e., as terrestrial or Jovian; inner or outer.

o. giving the distance, rates of revolution and rotation, mass, atmospheric conditions, and other properties of each planet in the solar system.

p. noting any features which are characteristic of only one planet: i.e., polar caps of Mars, red spot of Jupiter, etc., and compare as to direction of revolution and rotation.

q. comparing the number of satellites of the planets and their relative effect on the planet.

r. giving brief descriptions of comets, minor planets and meteoroids.

s. defining zodiacal light, solar wind, effective temperature.

t. listing several methods by which masses, rotation rates and distances are determined.

u. indicating the premises of the kinetic theory of gases, noting the dependence of speed on temperature.

v. explaining qualitatively the relationships between temperature and gravitational attraction as far as atmosphere retention is concerned.

w. indicating the major features known about minor planets: location, masses, size, etc..

x. suggesting a possible explanation of the existence of the minor planets.

y. defining: Kirkwood's gaps, Trojan asteroids.

z. indicating the various parts of a comet and also the composition of these parts.

aa. stating the elements of the orbit of "Halley's" and other well known comets.

bb. defining: meteoroid, meteorite, meteor, fireball, bolide, meteor shower, radiant, zodiacal light, gegenschein, tektite, ablation.

cc. explaining the observation of more meteors after midnight.

dd. explaining the apparent association of some meteor showers with comets.

ee. distinguishing the types of meteorites and the relative abundance of each type.

ff. indicating the size of micrometeorites and zodiacal dust.

gg. suggesting the possible origins of comets and of meteors.

4. The student will be able to use various simple astronomical instruments and understand their application to the field by:

a. defining: lens aperture, focal length, optic axis, focal plane, scale, brightness, resolution, aberration, eyepiece, objective.

b. relating the properties of the image to focal length and lens aperture.

c. calculating magnification and resolving power of telescopes.

d. distinguishing between reflecting and refracting telescopes noting the advantages and disadvantages of each.

e. describing each of the following types of telescope: Newtonian, Schmidt, prime focus, Cassegrain, Coude.

f. explaining the advantage of an equatorial mount for an astronomical telescope.

g. listing several methods by which images are observed.

h. defining: spectroscopy, spectroscope, spectrograph.

i. describing a radio telescope relating its resolution and light gathering power to that of optical telescopes.

D. Criteria Performance Standard:

Upon successful completion of the course the student will, with a minimum of 70% accuracy, demonstrate mastery of each of the above stated objectives through classroom measures developed by individual course instructors.

Revised 8/9/83	Online 2000-1.
DBT 6/24/85	Effective Session I, 2001 (20011).
SCN change 3/10/86
Effective Session I, 1987-88
Reviewed C&I 2/5/91
3 YR C&I Review 8/94
C&I 12/6/94, eff II, 1994-95
DBT 4/18/95
Effective Session I, 1995-96
3 Yr Review 1999-2000.