Presentation is loading. Please wait.

Presentation is loading. Please wait.

ASTR 1101-001 Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture14]

Published byDerek Golden Modified over 8 years ago

Similar presentations

Presentation on theme: "ASTR 1101-001 Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture14]"— Presentation transcript:

1 ASTR 1101-001 Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture14]

2 Scientific utility of the Copernican Heliocentric Model Can deduce the true “sidereal” (as opposed to readily measured “synodic”) orbital periods of each of the planets [see textbook BOX 4-1 and Table 4-1] Can deduce the distance that each planet is from the Sun, relative to the Earth’s distance from the Sun (1 AU); [see textbook discussion associated with Table 4-2]

3 Scientific utility of the Copernican Heliocentric Model Can deduce the true “sidereal” (as opposed to readily measured “synodic”) orbital periods of each of the planets [see textbook BOX 4-1 and Table 4-1] Can deduce the distance that each planet is from the Sun, relative to the Earth’s distance from the Sun (1 AU); [see textbook discussion associated with Table 4-2]

4 Determining the size of the orbit of Mars Suppose that at sunrise, Mars is on the western horizon; does Mars lie in Direction #1 or direction #2? Suppose that at sunrise, Mars is seen directly overhead; does Mars lie in Direction #1 or direction #2?

5 Determining the size of the orbit of Mars At sunrise, if Mars is on the western horizon, Mars must lie in Direction #1. At sunrise, if Mars is seen directly overhead, Mars must lie in Direction #2.

6 Determining the size of the orbit of Mars But until we know the size of the orbit of Mars, we don’t know precisely where it resides along either line of sight. Consider the three possible orbits shown on the next few slides …

7 Determining the size of the orbit of Mars But until we know the size of the orbit of Mars, we don’t know precisely where it resides along either line of sight. Consider the three possible orbits shown on the next few slides …

8 Determining the size of the orbit of Mars

9

10

11

12

13 So, by measuring the amount of time it takes Mars to travel from point “A” to point “B” each orbit, Copernicus was able to determine the size of the orbit of Mars (and of Jupiter, Saturn, Mercury, and Venus).

14 Determining the size of the orbit of Mars So, by measuring the amount of time it takes Mars to travel from point “A” to point “B” each orbit, Copernicus was able to determine the size of the orbit of Mars (and of Jupiter, Saturn, Mercury, and Venus).

15 Scientific utility of the Copernican Heliocentric Model Can deduce the true “sidereal” (as opposed to readily measured “synodic”) orbital periods of each of the planets [see textbook BOX 4-1 and Table 4-1] Can deduce the distance that each planet is from the Sun, relative to the Earth’s distance from the Sun (1 AU); [see textbook discussion associated with Table 4-2]

16 Summary Results (deduced by Copernicus) PlanetP (years) D (AU) P2P2 D3D3 Mercury0.2410.3870.058 Venus0.6150.7230.378 Earth1.000 1.00 Mars1.881.5243.533.54 Jupiter11.865.203141. Saturn29.469.554870. Uranus84.1019.1947070. Neptune164.8630.06627,200.

17 Summary Results (all 8 planets) PlanetP (years) D (AU) P2P2 D3D3 Mercury0.2410.3870.058 Venus0.6150.7230.378 Earth1.000 1.00 Mars1.881.5243.533.54 Jupiter11.865.203141. Saturn29.469.554870. Uranus84.1019.1947070. Neptune164.8630.06627,200.

18 Notice … There is a strong correlation between a planet’s orbital period and its distance from the Sun … Planets that are farther and farther from the Sun exhibit longer and longer orbital periods

19 Summary Results (all 8 planets) PlanetP (years) D (AU) P2P2 D3D3 Mercury0.2410.3870.058 Venus0.6150.7230.378 Earth1.000 1.00 Mars1.881.5243.533.54 Jupiter11.865.203141. Saturn29.469.554870. Uranus84.1019.1947070. Neptune164.8630.06627,200.

20 Additional Realization … (first noticed by Kepler) PlanetP (years) D (AU) P2P2 D3D3 Mercury0.2410.3870.058 Venus0.6150.7230.378 Earth1.000 1.00 Mars1.881.5243.533.54 Jupiter11.865.203141. Saturn29.469.554870. Uranus84.1019.1947070. Neptune164.8630.06627,200.

21 Additional Realization … (first noticed by Kepler) PlanetP (years) D (AU) P2P2 D3D3 Mercury0.2410.3870.058 Venus0.6150.7230.378 Earth1.000 1.00 Mars1.881.5243.533.54 Jupiter11.865.203141. Saturn29.469.554870. Uranus84.1019.1947070. Neptune164.8630.06627,200. P 2 = D 3 !!

22 P 2 = D 3 (works for all 8 planets) PlanetP (years) D (AU) P2P2 D3D3 Mercury0.2410.3870.058 Venus0.6150.7230.378 Earth1.000 1.00 Mars1.881.5243.533.54 Jupiter11.865.203141. Saturn29.469.554870. Uranus84.1019.1947070. Neptune164.8630.06627,200.

23 Kepler’s Observed Laws of Planetary Motion …

Download ppt "ASTR 1101-001 Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture14]"

Similar presentations

ASTR 1101-001 Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture17]

ASTR Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture17]
ASTR 1101-001 Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture11]

ASTR Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture11]
ASTR 1101-001 Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture07]

ASTR Spring 2008 Joel E. Tohline, Alumni Professor 247 Nicholson Hall [Slides from Lecture07]
N U Neptune crossing 3:22:1 Plutinos classical KBOs scattered KBOs N U.

N U Neptune crossing 3:22:1 Plutinos classical KBOs scattered KBOs N U.
Earth Aristotle BC 384-322 Aristotle Geocentric model.

Earth Aristotle BC Aristotle Geocentric model.
Announcements Homework 3 due Monday Test next week: Wednesday or Thursday (your choice); at SL 228 testing center; one hour time limit; no calculators;

Announcements Homework 3 due Monday Test next week: Wednesday or Thursday (your choice); at SL 228 testing center; one hour time limit; no calculators;
Vocabulary.  Our solar system includes the sun, the planets and many smaller objects.

Vocabulary.  Our solar system includes the sun, the planets and many smaller objects.
Models of the solar system (Ch.29.1). 1 st model of the solar system Aristotle (300’s BC) said solar system was geocentric.

Models of the solar system (Ch.29.1). 1 st model of the solar system Aristotle (300’s BC) said solar system was geocentric.
Models of the Solar System. The observations that you have been making of the Sun, Moon and stars were the same observations made by early scientists.

Models of the Solar System. The observations that you have been making of the Sun, Moon and stars were the same observations made by early scientists.
Planet Order Create an easy way to remember the names of the planets in order from the Sun. Make up a silly sentence. Each word in the sentence should.

Planet Order Create an easy way to remember the names of the planets in order from the Sun. Make up a silly sentence. Each word in the sentence should.
Observing the solar system

Observing the solar system
My Solar System Slide Show YOUR NAME.

My Solar System Slide Show YOUR NAME.
By: ? & ? Grade 6-1 The Planet’s chart PlanetPeriod of rotation Orbiting the sun Mercury59 days88 days Venus243 days225 days Earth23.9 hours365..2 days.

By: ? & ? Grade 6-1 The Planet’s chart PlanetPeriod of rotation Orbiting the sun Mercury59 days88 days Venus243 days225 days Earth23.9 hours days.
Solar System Introduction to Solar System M. Nauman Bajwa Robina Jahangir The City School.

Solar System Introduction to Solar System M. Nauman Bajwa Robina Jahangir The City School.
Welcome to... A Game of X’s and O’s. 789 456 123.

Welcome to... A Game of X’s and O’s
The Solar System. Mercury Mercury is the closest planet to the sun. Mercury is the closest planet to the sun. Mercury is the eighth largest planet. Mercury.

The Solar System. Mercury Mercury is the closest planet to the sun. Mercury is the closest planet to the sun. Mercury is the eighth largest planet. Mercury.
Mercury  The closest planet to the sun.  It has no moons.  It has 38% gravity.  It takes 88 days to orbit the sun.

Mercury  The closest planet to the sun.  It has no moons.  It has 38% gravity.  It takes 88 days to orbit the sun.
What do you notice about the Orbit of the Planet’s compared to the Comet’s?

What do you notice about the Orbit of the Planet’s compared to the Comet’s?
UNIT NINE: Matter and Motion in the Universe  Chapter 26 The Solar System  Chapter 27 Stars  Chapter 28 Exploring the Universe.

UNIT NINE: Matter and Motion in the Universe  Chapter 26 The Solar System  Chapter 27 Stars  Chapter 28 Exploring the Universe.
Today’s topics Orbits Parallax Angular size and physical size Precession Reading sections 1.5, 2.6, 4.1-4.7.

Today’s topics Orbits Parallax Angular size and physical size Precession Reading sections 1.5, 2.6,

Similar presentations

Ads by Google