1. Astronomical Terms Rotation Motion around an axis Produces day/night
From: physicalgeography.net

2. Astronomical Terms Revolution Motion around another object; orbiting
Produces seasons
From: science-class.net

3. Astronomical Terms Orbital period Time required for one revolution
Length of one year for a given planet
school-for-champions.com

4. Astronomical Terms Orbital distance Average distance from the Sun
Solar system shown to size and distance scale
From: commons.wikimedia.org

5. Astronomical Terms Astronomical unit (AU) Distance from Earth to Sun
Used as a “measuring stick” for solar system distances
From: wchs-astronomy.wikispaces.com

6. Astronomical Terms Parallax
Apparent shift of objects due to motion of observer
Stellar parallax:
apparent shift of stars due to Earth’s movement around Sun

7. Astronomical Terms Geocentric: Earth-centered
Heliocentric: Sun-centered

8. ORIGINS OF ASTRONOMY Ancient Greece (600 BCE – 150 CE)
Islamic Golden Age (700s-1400s)
European Renaissance (1400s-1700s)
Earth Motions
Earth-Moon System

9. The Sun revolves around the Earth…
…and so do the other planets and the stars

10. Geocentrism: Evidence
We don’t feel the Earth moving, or fly off of it
The Earth is far too massive to be able to move
Stars don’t shift position over the course of each year (stellar parallax)

11. Ancient Greece (600 BCE – 150 CE)
PSCI 131: Origins of Astronomy –Ancient Greece
Ancient Greece
(600 BCE – 150 CE)

12. Ancient Greek Astronomy
PSCI 131: Origins of Astronomy –Ancient Greece
Ancient Greek Astronomy
The ancient Greeks knew the Earth is spherical
TRUE or FALSE?

13. Ancient Greek Astronomy
PSCI 131: Origins of Astronomy –Ancient Greece
Ancient Greek Astronomy
The ancient Greeks knew the Earth is spherical
TRUE

14. Ancient Greek Astronomy
PSCI 131: Origins of Astronomy –Ancient Greece
Ancient Greek Astronomy
The ancient Greeks knew the Earth’s true circumference (distance around the equator).
TRUE or FALSE?

15. Ancient Greek Astronomy
PSCI 131: Origins of Astronomy –Ancient Greece
Ancient Greek Astronomy
The ancient Greeks knew the Earth’s true circumference (distance around the equator).
TRUE

16. Ancient Greek Astronomy
PSCI 131: Origins of Astronomy –Ancient Greece
Ancient Greek Astronomy
The ancient Greeks knew about Saturn’s rings.
TRUE or FALSE?

17. Ancient Greek Astronomy
PSCI 131: Origins of Astronomy –Ancient Greece
Ancient Greek Astronomy
The ancient Greeks knew about Saturn’s rings.
FALSE (can’t be seen without a telescope)

18. Assumptions of the Ancient Greeks
PSCI 131: Origins of Astronomy – Ancient Greece
Assumptions of the Ancient Greeks
Universe
Earth
Seven “planetai”
Stars
Geocentrism
Celestial immutability
From redorbit.com

19. Important Discoveries
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries
Earth is spherical
Aristotle
Observation of lunar eclipses
What evidence did he observe?
From 8planets.co.uk

20. Important Discoveries
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries
Earth is spherical
What would Earth’s shadow look like if Earth were a flat disk? ? ? ?

21. Important Discoveries
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries
Earth’s circumference
Eratosthenes
Measuring angle of shadows
Basic geometry
Eratosthenes, BCE
From 3villagecsd.k12.ny.us

22. Important Discoveries: Earth’s circumference
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries: Earth’s circumference
Two ways to measure circumference
Degrees and length (stadion: ancient unit of length)
Earth’s circumf. = 360 degrees = ____ stadia
Need distance between two points in degrees and stadia
Distance from Syene to Alexandria in stadia was known to be 5000 stadia (about 480 miles) ?

23. Important Discoveries: Earth’s circumference
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries: Earth’s circumference
How did Eratosthenes find distance in degrees?
Angle of shadows in both cities on same day
At Syene: no shadow
At Alexandria: shadow made 7 degree angle

24. Important Discoveries: Earth’s circumference
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries: Earth’s circumference
Since 360°÷ 7°= about 50, Earth’s circumference must be about 50 times the Syene-Alexandria distance
5000 stadia x 50 = 250,000 stadia or 24,500 miles (actual: 24,901 mi)

25. Important Discoveries
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries
Heliocentric (sun-centered) solar system
Aristarchus
Sun much larger than Earth, further away than Moon
Basic geometry
From amazing-space.stsci.edu

26. Important Discoveries
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries
Rejection of heliocentric model
Predicted stellar parallax, but none was observed
Need a telescope to see it
Aristotle championed geocentric model

27. Important Discoveries
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries
Ptolemaic System
Ptolemy
Geocentric model
First organized explanation of celestial motion

28. Important Discoveries: Ptolemaic System
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries: Ptolemaic System
Deferent: orbital path
Epicycles: smaller circles
Used to explain retrograde motion

29. Important Discoveries: Ptolemaic System
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries: Ptolemaic System
Retrograde motion: “backward” motion of a planet along its orbital path
The Ptolemaic System used epicycles to explain retrograde motion

30. Important Discoveries: Ptolemaic System
PSCI 131: Origins of Astronomy – Ancient Greece
Important Discoveries: Ptolemaic System
Retrograde motion is really an illusion
Earth passes Mars in its orbit; Mars appears to move backward as seen from Earth

31. Islamic Golden Age (700s – 1400s)
PSCI 131: Origins of Astronomy
Islamic Golden Age
(700s – 1400s)
Preserved and expanded work of ancient Greeks and Indians
Detailed star catalogs, many observatories
Most star names are Arabic
Altair, Deneb, Aldebaran, etc.

32. European Renaissance (1400s – 1700s)
PSCI 131: Origins of Astronomy –European Renaissance
European Renaissance
(1400s – 1700s)

33. Timeline: Nicolaus Copernicus
PSCI 131: Origins of Astronomy – European Renaissance
Timeline: Nicolaus Copernicus
Copernicus
1473
1543
1400
1776
1492
1450
First printing press

34. Nicolaus Copernicus “Copernican Revolution” Heliocentrism
PSCI 131: Origins of Astronomy – European Renaissance
Nicolaus Copernicus
“Copernican Revolution”
Heliocentrism
Set stage for later discoveries

35. PSCI 131: Origins of Astronomy – European Renaissance
Timeline: Tycho Brahe
Copernicus
1473
1543
1400
1776
1492
1450
1546
1601
First printing press
Brahe

36. Tycho Brahe Very precise astronomical observations Geocentrist
PSCI 131: Origins of Astronomy – European Renaissance
Tycho Brahe
Very precise astronomical observations
Without a telescope
Geocentrist
Apparent absence of stellar parallax

37. Timeline: Johannes Kepler
PSCI 131: Origins of Astronomy – European Renaissance
Timeline: Johannes Kepler
Copernicus
Kepler
1473
1543
1571
1630
1400
1776
1492
1450
1546
1601
First printing press
Brahe

38. Johannes Kepler Brahe’s assistant Used Brahe’s observations
PSCI 131: Origins of Astronomy – European Renaissance
Johannes Kepler
Brahe’s assistant
Used Brahe’s observations
To prove heliocentrism
To develop laws of planetary motion still in use today

39. First Law of Planetary Motion
PSCI 131: Origins of Astronomy – European Renaissance - Kepler
First Law of Planetary Motion
Orbits are ellipses, not circles
Sun located at one focus of the ellipse
The pushpins are at the foci of the ellipse

40. First Law of Planetary Motion
PSCI 131: Origins of Astronomy – European Renaissance - Kepler
First Law of Planetary Motion
Orbits are ellipses, not circles
Sun located at one focus of the ellipse
From: csep10.phys.utk.edu

41. Second Law of Planetary Motion
PSCI 131: Origins of Astronomy – European Renaissance - Kepler
Second Law of Planetary Motion
Law of equal areas
During a given amount of time, a planet will always “sweep out” the same area in its orbit over that time
From: dallaskasaboski.blogspot.com

42. Second Law of Planetary Motion
PSCI 131: Origins of Astronomy – European Renaissance - Kepler
Second Law of Planetary Motion
Orbital speed varies inversely with orbital distance
Slower orbital speed
From:

43. Third Law of Planetary Motion
PSCI 131: Origins of Astronomy – European Renaissance - Kepler
Third Law of Planetary Motion
Orbital period proportional to orbital distance
p2 = d3
p: orbital period in Earth years
d: orbital distance in astronomical units (AUs)
Example: if p = 8 yrs, d = 4 AUs

44. Laws of Planetary Motion
PSCI 131: Origins of Astronomy – European Renaissance - Kepler
Laws of Planetary Motion
Significance
First mathematical model of celestial motion
Not based on philosophical assumptions

45. Timeline: Galileo Galilei
PSCI 131: Origins of Astronomy – European Renaissance
Timeline: Galileo Galilei
Kepler
1571
1630
Copernicus
1564
Galileo
1642
1473
1543
1400
1776
1492
1450
1546
1601
First printing press
Brahe

46. Galileo Galilei “Father of modern observational science”
PSCI 131: Origins of Astronomy – European Renaissance
Galileo Galilei
“Father of modern observational science”
Improvements to telescopes
Did not invent them
First astronomer to use telescope

47. The Galilean Moons Discovered four of Jupiter’s moons
PSCI 131: Origins of Astronomy – European Renaissance - Galileo
The Galilean Moons
Discovered four of Jupiter’s moons
Io, Ganymede, Callisto, Europa
First observation of moons other than Earth’s
Showed that Earth isn’t unique in having a natural satellite
Sizes of the Galilean moons shown relative to Jupiter
From: en.wikipedia.org

48. PSCI 131: Origins of Astronomy – European Renaissance - Galileo
The Galilean Moons
Galileo’s notebook showing changing positions of Galilean moons over two weeks
Jupiter and the Galilean moons through a small telescope, as Galileo saw them
From: splung.com
From: physics.wisc.edu

49. PSCI 131: Origins of Astronomy – European Renaissance - Galileo
The Phases of Venus
Observed that Venus goes through phases like Earth’s moon
Proof of heliocentrism
From: oneminuteastronomer.com

50. Sunspots Refuted celestial immutability
PSCI 131: Origins of Astronomy – European Renaissance - Galileo
Sunspots
Refuted celestial immutability
Series of Galileo’s 1612 sketches in a “flip-book” animation
Sunspots through a modern telescope
From: galileo.rice.edu
From: galileo.rice.edu

51. Timeline: Isaac Newton
PSCI 131: Origins of Astronomy – European Renaissance
Timeline: Isaac Newton
Kepler
1571
1630
Copernicus
1564
Galileo
1642
1473
1543
1400
1776
1492
1450
1546
1601
1642
1727
First printing press
Newton
Brahe

52. Sir Isaac Newton Law of Universal Gravitation Law of Inertia
PSCI 131: Origins of Astronomy – European Renaissance
Sir Isaac Newton
Law of Universal Gravitation
Law of Inertia
Explained why planets move in orbits

53. Universal Gravitation
PSCI 131: Origins of Astronomy – European Renaissance - Newton
Universal Gravitation
All objects in the universe exert an attractional force on each other
Force increases with mass and decreases with distance

54. Universal Gravitation
PSCI 131: Origins of Astronomy – European Renaissance - Newton
Universal Gravitation

55. Law of Inertia (Newton’s First Law)
PSCI 131: Origins of Astronomy – European Renaissance - Newton
Law of Inertia (Newton’s First Law)
An object in motion continues in motion with the same speed and in the same direction unless acted upon by an external force
From: drcruzan.com

56. Gravity + Inertia = Orbit
PSCI 131: Origins of Astronomy – European Renaissance - Newton
Gravity + Inertia = Orbit
An orbit is a balance between gravity and inertia

57. PSCI 131: Origins of Astronomy –Earth Motions

58. Rotation Solar day Sidereal day
PSCI 131: Origins of Astronomy –Earth Motions
Rotation
Solar day
Time from noon on one day to noon the next day: 24 hours
Sidereal day
Time required for a star to return to the same position on two successive nights: 23 hrs 56 minutes

59. Revolution Period of revolution: 365.25 days
PSCI 131: Origins of Astronomy –Earth Motions
Revolution
Period of revolution: days
Leap year
Perihelion: closest to Sun (January)
Aphelion: furthest from Sun (July)
Solstices & Equinoxes

60. Revolution: Perihelion & aphelion
PSCI 131: Origins of Astronomy –Earth Motions
Revolution: Perihelion & aphelion
From: universetoday.com

61. Revolution: Solstices & equinoxes
PSCI 131: Origins of Astronomy –Earth Motions
Revolution: Solstices & equinoxes
From: oceanservice.noaa.gov

62. Precession Wobble of Earth on its axis; 26,000-yr cycle
PSCI 131: Origins of Astronomy –Earth Motions
Precession
Wobble of Earth on its axis; 26,000-yr cycle

63. PSCI 131: Origins of Astronomy –Earth-Moon System
The Earth-Moon System

64. The Earth-Moon System Mean Earth-Moon distance: ~238,000 mi
PSCI 131: Origins of Astronomy –Earth-Moon System
The Earth-Moon System
Mean Earth-Moon distance: ~238,000 mi
Period of rotation: 27.5 days
Period of revolution: 27.5 days
“Synchronous” orbit
Same side always faces Earth

65. Lunar Phases Half of lunar surface always lit
PSCI 131: Origins of Astronomy –Earth-Moon System
Lunar Phases
Half of lunar surface always lit
Exception: lunar eclipse
Current phase depends on how much of lit surface is visible from Earth

66. PSCI 131: Origins of Astronomy – Earth-Moon System-Lunar Phases

67. End of Origins of Astronomy
PSCI 131: Origins of Astronomy
End of Origins of Astronomy