Objection (Parallax)
... Earth, moves in circles, called epicycles, on their own orbits, which explains both retrograde motion and planets' changing brightness Since the system wasn't totally accurate for predicting planetary motion, Ptolemy modified the model, moving the Earth slightly out of center This system goes unchal ...
... Earth, moves in circles, called epicycles, on their own orbits, which explains both retrograde motion and planets' changing brightness Since the system wasn't totally accurate for predicting planetary motion, Ptolemy modified the model, moving the Earth slightly out of center This system goes unchal ...
Astro history 1
... Earth’s orbiting of the Sun The nearest stars are much farther away than the Greeks thought. So the parallax angles of the star are so small, that you need a telescope to observe them. ...
... Earth’s orbiting of the Sun The nearest stars are much farther away than the Greeks thought. So the parallax angles of the star are so small, that you need a telescope to observe them. ...
Scale Model of the Solar System
... 1:1,000,000,000. This sounds difficult to do but actually it’s very easy because at this scale 1mm = 1,000 kilometres. Good approximations of the sizes of the planets are shown in the table below. Object Sun Mercury Venus Earth Mars Asteroid belt Jupiter Saturn Uranus Neptune Pluto Proxima Centauri ...
... 1:1,000,000,000. This sounds difficult to do but actually it’s very easy because at this scale 1mm = 1,000 kilometres. Good approximations of the sizes of the planets are shown in the table below. Object Sun Mercury Venus Earth Mars Asteroid belt Jupiter Saturn Uranus Neptune Pluto Proxima Centauri ...
Orbits of the planets - University of Iowa Astrophysics
... move together with the epicycle of Venus centered on a line between the Earth and the Sun • Then, Venus can never be the opposite side of the Sun from the Earth, so it can never have gibbous phases – no “full Venus”. ...
... move together with the epicycle of Venus centered on a line between the Earth and the Sun • Then, Venus can never be the opposite side of the Sun from the Earth, so it can never have gibbous phases – no “full Venus”. ...
chart_set_2 - Physics and Astronomy
... However, Ptolemy (c. A.D. 140) invented a model where planets circle in “epicycles” that orbit the Earth. This helped to explain retrograde motion for a long time, until astronomical observations became more precise. The Ptolemaic Model. ...
... However, Ptolemy (c. A.D. 140) invented a model where planets circle in “epicycles” that orbit the Earth. This helped to explain retrograde motion for a long time, until astronomical observations became more precise. The Ptolemaic Model. ...
Solar System Cloze
... Fill in the blanks below with words from this box: Neptune gas giants Pluto solar Mars nine asteroids Jupiter temperature orbit water Saturn dinosaurs Earth Venus Mercury ...
... Fill in the blanks below with words from this box: Neptune gas giants Pluto solar Mars nine asteroids Jupiter temperature orbit water Saturn dinosaurs Earth Venus Mercury ...
Revolutions of Earth
... To an observer, Earth appears to be the center of the universe. That is what the ancient Greeks believed. This view is called the geocentric model, or "Earth-centered" model, of the universe. In the geocentric model, the sky, or heavens, are a set of spheres layered on top of one another. Each objec ...
... To an observer, Earth appears to be the center of the universe. That is what the ancient Greeks believed. This view is called the geocentric model, or "Earth-centered" model, of the universe. In the geocentric model, the sky, or heavens, are a set of spheres layered on top of one another. Each objec ...
SOL Study Book
... Marshmallows 5. Jupiter, Saturn, Uranus, and Neptune have rings 6. Pluto is considered a “dwarf planet” and is smaller than seven moons in our solar system 7. Inner Planets Include: Earth, Mercury, Venus, and Mars Moon Phases ...
... Marshmallows 5. Jupiter, Saturn, Uranus, and Neptune have rings 6. Pluto is considered a “dwarf planet” and is smaller than seven moons in our solar system 7. Inner Planets Include: Earth, Mercury, Venus, and Mars Moon Phases ...
Lecture #2 - Personal.psu.edu
... An object at rest will remain at rest, and an object moving in a straight line at constant speed will not change its motion, unless an external force ...
... An object at rest will remain at rest, and an object moving in a straight line at constant speed will not change its motion, unless an external force ...
Unit 2. The planets in the Solar System The Solar System: Consists
... covers three quarters of our planet. ...
... covers three quarters of our planet. ...
Which of the following represent the best explanation we currently
... ! A theory consists of a set of basic principles. ! These principles are often widely accepted. ...
... ! A theory consists of a set of basic principles. ! These principles are often widely accepted. ...
Review Sheet
... • Why summers on earth are hot and winters are cold. • How the Zodiac helps you to predict the future. • The phases of the moon; that is what causes them and what order they fall in. From Astronomy as a case history of science you should understand: • That science is a method for making sense of the ...
... • Why summers on earth are hot and winters are cold. • How the Zodiac helps you to predict the future. • The phases of the moon; that is what causes them and what order they fall in. From Astronomy as a case history of science you should understand: • That science is a method for making sense of the ...
powerpoint - Physics @ IUPUI
... • These circles were called epicycles. • The 2nd was Hipparchus (190-120 BCE) who helped further the ideas which would later be the Ptolemy model. • Hipparchus also discovered the precession of the earth and started the magnitude system for star brightness. ...
... • These circles were called epicycles. • The 2nd was Hipparchus (190-120 BCE) who helped further the ideas which would later be the Ptolemy model. • Hipparchus also discovered the precession of the earth and started the magnitude system for star brightness. ...
Our Solar System - Hardeman School
... Our Moon is many times smaller than Earth Many scientists think the Moon used to be a part of Earth The Moon causes Earths ocean tides too It reflects light from the sun ...
... Our Moon is many times smaller than Earth Many scientists think the Moon used to be a part of Earth The Moon causes Earths ocean tides too It reflects light from the sun ...
1. In Ptolemy`s geocentric model, the planet`s mo
... C) The Sun lies at one focus of an ellipse. D) Mars will retrograde when it reaches a certain position on its epicycle. E) Planetary orbits are elliptical in shape. 19. According to Copernicus, retrograde motion for Venus must occur around A) greatest elongation, when the planet is farthest from the ...
... C) The Sun lies at one focus of an ellipse. D) Mars will retrograde when it reaches a certain position on its epicycle. E) Planetary orbits are elliptical in shape. 19. According to Copernicus, retrograde motion for Venus must occur around A) greatest elongation, when the planet is farthest from the ...
![ASTRONOMY 101 SAMPLE FIRST EXAM [1] Kepler`s Law relating](http://s1.studyres.com/store/data/017742958_1-c5c5f19bce1080c6ad7c1fc92906a06f-300x300.png)
ASTRONOMY 101 SAMPLE FIRST EXAM [1] Kepler`s Law relating
... (a) the planet moves slower as it approaches nearer the sun. (b) the line between the Sun and the planet sweeps out equal areas in equal times. (c) it won’t need to stop for the comets going by. _______________________________________________________________ Match the name with the accomplishment: [ ...
... (a) the planet moves slower as it approaches nearer the sun. (b) the line between the Sun and the planet sweeps out equal areas in equal times. (c) it won’t need to stop for the comets going by. _______________________________________________________________ Match the name with the accomplishment: [ ...
Astronomy Test Review
... e. June 21 in southern Argentina (southern hemisphere) 8. Why can we see some stars all year round, but others only during certain seasons? 9. Draw what the moon looks like in each of the following phases: a. Waxing crescent b. Waning gibbous c. First quarter 10. Why is it that we can see Jupiter, M ...
... e. June 21 in southern Argentina (southern hemisphere) 8. Why can we see some stars all year round, but others only during certain seasons? 9. Draw what the moon looks like in each of the following phases: a. Waxing crescent b. Waning gibbous c. First quarter 10. Why is it that we can see Jupiter, M ...
Greek and Hellenistic Astronomy
... As Babylonian astronomers had already noted, the outer planets (Mars, Jupiter and Saturn) do not move in uniform speed and direction with respect to the fixed stars, but, at times, are also observed to become stationary or move in opposite (westward or retrograde) direction. The inner planets (Merc ...
... As Babylonian astronomers had already noted, the outer planets (Mars, Jupiter and Saturn) do not move in uniform speed and direction with respect to the fixed stars, but, at times, are also observed to become stationary or move in opposite (westward or retrograde) direction. The inner planets (Merc ...
Space Jeopardy 2
... The colour the Northern Lights appear when the Sun’s solar wind travel along Earth’s magnetic field and strike particles of ...
... The colour the Northern Lights appear when the Sun’s solar wind travel along Earth’s magnetic field and strike particles of ...
Quarter 3 Benchmark Study Guide w/ Answer Key
... 22. What does the atmosphere of a gas giant look like? deep, with many clouds 23. A ring is chunks of ice orbiting a gas giant's equator 24. Comets and asteroids both orbit the sun 25. A brief streak of light from a falling object is a meteor 26. Venus dense atmosphere causes it to have a more unif ...
... 22. What does the atmosphere of a gas giant look like? deep, with many clouds 23. A ring is chunks of ice orbiting a gas giant's equator 24. Comets and asteroids both orbit the sun 25. A brief streak of light from a falling object is a meteor 26. Venus dense atmosphere causes it to have a more unif ...
Unit 3 - Section 8.9 2011 Celestrial Objects from Earth
... is in orbit around the Earth, not the Sun. The stars are distant objects that do not revolve around the Sun. Instead, the Earth is assumed to rotate once in 24 hours causing the stars to appear to revolve around the Earth in the opposite direction By banishing the idea that the Earth was the centre ...
... is in orbit around the Earth, not the Sun. The stars are distant objects that do not revolve around the Sun. Instead, the Earth is assumed to rotate once in 24 hours causing the stars to appear to revolve around the Earth in the opposite direction By banishing the idea that the Earth was the centre ...
Solar System Unit Review - Parma City School District
... What is a group of solar systems held together by gravity? ...
... What is a group of solar systems held together by gravity? ...
Geocentric model
In astronomy, the geocentric model (also known as geocentrism, or the Ptolemaic system) is a description of the cosmos where Earth is at the orbital center of all celestial bodies. This model served as the predominant cosmological system in many ancient civilizations such as ancient Greece including the noteworthy systems of Aristotle (see Aristotelian physics) and Ptolemy. As such, they believed that the Sun, Moon, stars, and naked eye planets circled Earth.Two commonly made observations supported the idea that Earth was the center of the Universe. The stars, the sun, and planets appear to revolve around Earth each day, making Earth the center of that system. The stars were thought to be on a celestial sphere, with the earth at its center, that rotated each day, using a line through the north and south pole as an axis. The stars closest to the equator appeared to rise and fall the greatest distance, but each star circled back to its rising point each day. The second observation supporting the geocentric model was that the Earth does not seem to move from the perspective of an Earth-bound observer, and that it is solid, stable, and unmoving.Ancient Roman and medieval philosophers usually combined the geocentric model with a spherical Earth. It is not the same as the older flat Earth model implied in some mythology, as was the case with the biblical and postbiblical Latin cosmology. The ancient Jewish Babylonian uranography pictured a flat Earth with a dome-shaped rigid canopy named firmament placed over it. (רקיע- rāqîa').However, the ancient Greeks believed that the motions of the planets were circular and not elliptical, a view that was not challenged in Western culture until the 17th century through the synthesis of theories by Copernicus and Kepler.The astronomical predictions of Ptolemy's geocentric model were used to prepare astrological and astronomical charts for over 1500 years. The geocentric model held sway into the early modern age, but from the late 16th century onward was gradually superseded by the heliocentric model of Copernicus, Galileo and Kepler. There was much resistance to the transition between these two theories. Christian theologians were reluctant to reject a theory that agreed with Bible passages (e.g. ""Sun, stand you still upon Gibeon"", Joshua 10:12 – King James 2000 Bible). Others felt a new, unknown theory could not subvert an accepted consensus for geocentrism.