1 / 28

More About Individual Term Projects

More About Individual Term Projects. Next Tuesday. Meet at Abrams Planetarium at the usual time. Aurora. A few words on Huygens. Titan – Saturn’s largest moon. First Detailed images of the surface. From 16.2 km up. From 8km up. Mosaic of descent images. *Deadline*.

Download Presentation

More About Individual Term Projects

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. More About Individual Term Projects

  2. Next Tuesday • Meet at Abrams Planetarium at the usual time

  3. Aurora

  4. A few words on Huygens

  5. Titan – Saturn’s largest moon

  6. First Detailed images of the surface

  7. From 16.2 km up

  8. From 8km up

  9. Mosaic of descent images

  10. *Deadline* • By next Tuesday, I would like you each to turn in a one page description of your individual semester project

  11. Sample Projects • Moon position • Photographing planet motions • Observing a variable star

  12. Moon Position Project • What you need: • A chart of the night sky showing the constellations visible at the time you are observing (Abrams sky calendar charts are good, but you may need more than the January chart)

  13. Mark location of the moon with respect to the stars

  14. In a notebook record: • The date and time of each observation • The phase of the moon (make a sketch) • Do not let your observation be influenced by planetarium software or other predictions

  15. Goal • Do this on perhaps 10-15 nights during the semester • Use your observations to determine • The sidereal period of the moon • The synodic period of the moon • Estimate the uncertainty of each period And compare these with the “book” values

  16. Periods • Sidereal period: The “true” orbital period of the Moon. How long it takes the moon to return to the same location with respect to the stars • Synodic period: How long it takes to return to the same phase; based upon the position of the Sun and Moon with respect to the earth

  17. Planet Motion Project • For this project, you will need a camera (most easily a digital camera) that can take time exposures of a few seconds duration • For this project, it is OK to work as a team of two people

  18. Step 1: Image the planet and the background stars (5 or 6 times in the semester) • Saturn and/or Jupiter are most easily done this semester

  19. Step 2 • Measure the position of the planet on the image with respect to several stars • Use the known right ascension and declination of the stars to determine the right ascension and declination of the planet on each date • Estimate the uncertainty of your measured positions

  20. Step 3 • Plot the changing position of the planet and compare your results with the predicted motion of the planet

  21. Variable Star Project • Two possible targets • Delta Cephei • Algol (easier for naked eye observations from campus)

  22. Delta Cephei Project • Check out the “observing delta Cephei” tutorial at the AAVSO website: http://hoa.aavso.org/observing.html Following the steps outlined there,estimate the brightness of Delta Cephei on 12 or more nights during the semester Calculate the “Julian Date” of each of your observations using the website http://wwwmacho.mcmaster.ca/JAVA/JD.html

  23. Make a light curve • Estimate the pulsation period of Delta Cephei from your observations • Calculate the “phase” of each of your measurements: Phase = Julian Date/period (Keep only the part after the decimal point, i.e., if the phase comes out to be 5.43 keep just the 0.43)

  24. Plot a light curve • Plot the observed magnitude versus phase (your plot may not look this nice)

  25. Algol • Brighter than Delta Cephei and higher overhead in the evening (easier to observe without binoculars) • Use your chart of Algol (you can download another from the AAVSO website if needed) to estimate the brightness of the star, recording date and time

  26. Measure the brightness of Algol on at least 10 nights • On at least one night when Algol is predicted to undergo an eclipse, measure its brightness several times over the span of 3 or 4 hours around the time of minimum • Predicted times of minimum can be obtained at the website • http://skyandtelescope.com/observing/objects/variablestars/article_108_1.asp

  27. Plot the light curve, as in the case of Delta Cephei • In this case, you may use the known period of 2.8673 days if your observations do not let you determine the period independently. You will need to observe more than one minimum if you want to independently determine the period of Algol.

  28. Other independent projects • You may devise an independent project of your own, but you will have to check it out with me before you do it

More Related