Lab-3 The-Orbit-of-Mars

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Astronomy

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Apr 3, 2024

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The Orbit of Mars Materials: protractor, compass, centimeter ruler, paper, scientific calculator, Textbook. Object: To reconstruct the approximate orbit of Mars by using some of Tycho's data. Tycho Brahe collected a number of observations of the positions of Mars as seen from Earth during the latter part of the 16th century. In order to plot the orbit of Mars it is necessary not only to know where Mars was in relation to the earth but also to know where the earth was in relation to the Sun. Mars’s period of revolution about the Sun is 687 days. So any two observations of the position of Mars separated by exactly 687 days would view Mars at the same position in its orbit. Where those two lines of sight (from Earth to Mars) crossed would be Mars’s position in space. The table below lists pairs of Mars positions observed by Tycho and arranged by Kepler to be 687 days apart. These were recorded in Keplers book of 1609, Astronomia Nova (“The New Astronomy”). Date Heliocentric Longitude of Earth Geocentric Longitude of Mars 1585 Feb 17 159° 135° 1587 Jan 05 115° 182° 1591 Sep 19 284° 1593 Aug 06 323° 347° 1593 Dec 07 86° 1595 Oct. 25 42° 50° 1587 Mar 28 197° 168° 1589 Feb 12 154° 219° 1585 Mar 10 180° 132° 1587 Jan 26 136° 185° Procedure: You may work in groups. However, EACH student will turn in the results of the following procedures and your own sketch! 1. Place the graph paper in front of you with the long side horizontal. Place a small dot, representing the Sun, near the center of your graph paper. Label the dot "Sun". Draw a straight line from the center (the Sun) to the right-hand edge. Label this line the “autumnal equinox.” This line represents the 0° direction in space. All angles should be measured counter-clockwise from this direction 2. Draw a circle of radius 5.0 centimeters centered on the Sun. This circle represents the orbit of Earth. In reality, the Earth’s orbital eccentricity is 0.016, or 1.6% deviation from perfect circularity. Note: This scale means that 5.0 cm = 1 A.U. Where 1 A.U. is the average distance between the Earth and Sun (93 million
miles); Label this circle "Earth’s Orbit". 3. Using the protractor centered on the Sun with 0° toward the autumnal equinox, and using the heliocentric longitude of the Earth (as given in the table above) plot the positions of the Earth with dots on the Earth’s orbit. You should label the date next to each of the 10 dots! 4. The observations of Mars are paired. Go to the first entry (Feb 17, 1885). Move the protractor so that the Earth is at the protractor’s center, but the 0° direction is still parallel to the autumnal equinox line. Find the geocentric longitude of Mars observed for that date and mark it. Draw a line in this direction starting from Earth and proceeding nearly to the edge of the page (as in figure 1). 5. Repeat step-4 for the second entry of the first observation pair (see figure-2). Continue this process for all data entries in table. 6. For each observation pair Mars is located at the intersection of the two lines. Put a conspicuous dot on each of the five intersections (as in figure 2). When completed you should have 5 paired lines that meet outside earth’s orbit. STOP if not and review steps 3 to 5! Figure 1 Figure 2 Figure 3 7. Kepler chose the first two sets of data to represent aphelion and perihelion respectively for Mars, mark these in drawing. Then, draw a line from the aphelion to the perihelion for Mars. This line should go through (or pass close to) the Sun. If not, something has gone wrong. This line is called the major axis of the orbit. (Today, half of this is known as the mean distance Sun-Earth). Measure the major axis in centimeters to the nearest millimeter (tenth of a centimeter) Major axis = 15.5 cm. 8. Find the middle of the major axis by dividing the length of the major axis by 2. This length is defined as the semi-major axis = 7.75 cm Mark the center of the major axis and label it “midpoint”. 9. Using the compass draw a circle representing Mars' orbit by placing the point of the compass on the midpoint and the pencil part either on the perihelion or aphelion points and making a circle. If you found the midpoint correctly your orbit should pass through both perihelion and aphelion points. Your diagram should look somewhat like the one in figure 3. The other three points of the orbit should pass quite close to the circle that you drew. No wonder Kepler and others initially thought that planetary orbits were circular! DO NOT continue if orbit does not look like figure 3, review for errors from step 1. 10. Calculate the length of the semi-major axis of the orbit of Mars in A.U. and in miles. Remember that on our drawing that 5 cm = 1 A.U. = 93 000 000 miles. Show your work! Semi-major axis = 1.496 A.U. Semi-major axis =139,061,888 miles 11. Look up the accepted value for Mars’s semi-major axis length in AU in the appendix of your textbook. Compare your calculated value against the accepted one by calculating the percent deviation, using the following formula. Show your work clearly. Note that to multiply by 100% means you multiply by 100 and attach the percent sign to the answer. % ????? =| 𝐴??????? ?𝑎𝑙??? 𝑦??? ?𝑎𝑙???𝑎??????? ?𝑎𝑙?? | × 100% (the bars in formula means the absolute value)
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