Presentation is loading. Please wait.

Presentation is loading. Please wait.

Ast 1001 lecture 4 -- 2007 Sept 13 (kd). 4. How Orbits Work Astronomy 1001, Sept 2007 – Prof. K. Davidson.

Published byAngel Hubbard Modified over 8 years ago

Similar presentations

Presentation on theme: "Ast 1001 lecture 4 -- 2007 Sept 13 (kd). 4. How Orbits Work Astronomy 1001, Sept 2007 – Prof. K. Davidson."— Presentation transcript:

1 Ast 1001 lecture 4 -- 2007 Sept 13 (kd)

2 4. How Orbits Work Astronomy 1001, Sept 2007 – Prof. K. Davidson

3 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) KEPLER’S LAWS (c. 1610)

4 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) 1. Each planet follows an elliptical orbit, with the Sun at one focus* 2. Equal areas in equal times 3. Period squared = radius cubed * (Note: the orbits aren’t aligned)

5 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) KEPLER’S FIRST LAW (except that planets’ orbits are usually more circular than this)

6 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) KEPLER’S SECOND LAW: “EQUAL AREAS IN EQUAL TIMES”

7 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) KEPLER’S THIRD LAW relates the speeds of different planets; those farther out move slower. If a = average distance from the Sun* and P = orbital period, then P 2 = (constant) x a 3. * (Distance is reckoned from the center of the Sun.)

8 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Kepler’s third law -- the numbers a (AU) P (yr) a 3 P 2 MERCURY 0.387 0.241 0.058 0.058 VENUS 0.723 0.615 0.378 0.378 EARTH 1.000 1.000 1.00 1.00 MARS 1.524 1.881 3.54 3.54 JUPITER 5.203 11.86 141 141 SATURN 9.54 29.46 868 868

9 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Isaac Newton (1642 – 1727)

10 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Newton’s theory of dynamics, also called mechanics Motions of objects impelled by forces

11 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Brief digression... A VECTOR IS A QUANTITY THAT HAS A DIRECTION IN SPACE. examples: ** POSITION ** ** VELOCITY ** ** ACCELERATION **

12 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) “vector addition”

13 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) VELOCITY tells us how POSITION changes with time (in all directions);

14 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) VELOCITY tells us how POSITION changes with time (in all directions); ACCELERATION tells us how VELOCITY changes with time (in all directions).

15 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) VELOCITY tells us how POSITION changes with time (in all directions); ACCELERATION tells us how VELOCITY changes with time (in all directions). So: If we know an object’s three-dimensional acceleration at all times, then we can predict its motion.

16 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) “If we know an object’s acceleration at all times, then we can predict its motion.” ( Newton invented a new kind of math specifically for this purpose: “differential calculus”, which concerns rates of change. )

17 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Newton also invented the concept of force in the modern sense. FORCE = MASS x ACCELERATION, or F = m a, or a = F / m. ( F and a are vectors; they have directions.)

18 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Newton’s crucial “thought experiment” (1665)

19 Ast 1001 lecture 4 -- 2007 Sept 13 (kd)

20

21 The Moon’s orbit around Earth r = 384000 km = about 60 x (radius of Earth), v = 3700 km/hr = 1.02 km/s. So the required acceleration toward earth is a = v 2 / r = 0.27 cm / s / s.

22 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Moon’s acceleration toward Earth is about 0.27 cm / s / s. So what? -- Our acceleration toward Earth is g = 980 cm / s / s. Newton noticed that these have the ratio 3600. 60 x farther makes gravity weaker by a factor of 3600 x. This is obviously 60 x 60 = 60 2 !

23 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Newton’s law of gravity: ( attractive force between M and m ) = G x M x m / (distance) 2. For instance, 3 x farther makes it 9 x weaker; 10 x farther makes it 100 x weaker.

24 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) THE “INVERSE SQUARE LAW” OF GRAVITY WAS ENOUGH TO EXPLAIN KEPLER’S LAWS! 1. Orbits are ellipses, Sun at one focus 2. Equal areas in equal times 3. Period squared = orbit radius cubed

25 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) NEWTON’S REVOLUTION WAS AS IMPORTANT AS COPERNICUS’. There are “laws of physics” that apply everywhere, from this room to the edge of the universe. In 1680 this was a breathtaking new idea! It led to modern physical science.

26 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) Newton’s influence on the following century -- “the age of reason”, at least for philosophers. His historical importance was recognized in his own time -- arguably “the most important man in the world”, outranking even Louis XIV.

27 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) ORBIT SHAPES: ELLIPSE, PARABOLA, HYPERBOLA

28 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) “CONIC SECTIONS”: CIRCLE ELLIPSE PARABOLA HYPERBOLA

29 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) ENERGY IN ORBITS -- KINETIC ENERGY -- POTENTIAL ENERGY K.E. + P.E. = constant The Roller Coaster analogy

30 Ast 1001 lecture 4 -- 2007 Sept 13 (kd) CELESTIAL MECHANICS (ORBITAL DYNAMICS) Kepler’s laws are not exactly true...

31 Ast 1001 lecture 4 -- 2007 Sept 13 (kd)

Download ppt "Ast 1001 lecture 4 -- 2007 Sept 13 (kd). 4. How Orbits Work Astronomy 1001, Sept 2007 – Prof. K. Davidson."

Similar presentations

How do we describe motion?

How do we describe motion?
Kepler’s Laws.

Kepler’s Laws.
The Beginning of Modern Astronomy

The Beginning of Modern Astronomy
© 2010 Pearson Education, Inc. Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.

© 2010 Pearson Education, Inc. Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.
Chapter 4 Making Sense of the Universe Understanding Motion, Energy, and Gravity.

Chapter 4 Making Sense of the Universe Understanding Motion, Energy, and Gravity.
Lecture Outline Chapter 4: Making Sense of the Universe Understanding Motion, Energy, and Gravity © 2015 Pearson Education, Inc.

Lecture Outline Chapter 4: Making Sense of the Universe Understanding Motion, Energy, and Gravity © 2015 Pearson Education, Inc.
Gravity Physics 6B Prepared by Vince Zaccone For Campus Learning Assistance Services at UCSB.

Gravity Physics 6B Prepared by Vince Zaccone For Campus Learning Assistance Services at UCSB.
Galileo, Newton and the Birth of Astrophysics

Galileo, Newton and the Birth of Astrophysics
Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.

Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.
Kepler’s Laws of Planetary Motion

Kepler’s Laws of Planetary Motion
Chapter 7 Review.

Chapter 7 Review.
Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.

Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.
Ancient Astronomy Neolithic Astronomy Stonehenge ~ 2800 – 1700 BCE.

Ancient Astronomy Neolithic Astronomy Stonehenge ~ 2800 – 1700 BCE.
Newton's derivation of the inverse square law of gravity From observations of the night sky, it was clear to Newton (and many before him) that there.

Newton's "derivation" of the inverse square law of gravity From observations of the night sky, it was clear to Newton (and many before him) that there.
Do our planets move?.

Do our planets move?.
Gravitation and the Waltz of the Planets Chapter Four.

Gravitation and the Waltz of the Planets Chapter Four.
Astro: Chapter 3-5. The birth of modern astronomy and of modern science dates from the 144 years between Copernicus’ book (1543) and Newton’s book (1687).

Astro: Chapter 3-5. The birth of modern astronomy and of modern science dates from the 144 years between Copernicus’ book (1543) and Newton’s book (1687).
Introduction to Gravity and Orbits. Isaac Newton Born in England in 1642 Invented calculus in early twenties Finally published work in gravity in 1687.

Introduction to Gravity and Orbits. Isaac Newton Born in England in 1642 Invented calculus in early twenties Finally published work in gravity in 1687.
Planets of the Solar System Section 2 Section 2: Models of the Solar System Preview Key Ideas Early Models Kepler’s Laws Newton’s Explanation of Kepler’s.

Planets of the Solar System Section 2 Section 2: Models of the Solar System Preview Key Ideas Early Models Kepler’s Laws Newton’s Explanation of Kepler’s.
Circular Motion; Gravitation

Circular Motion; Gravitation

Similar presentations

Ads by Google