Resources: Sample
Student Activities and Exercises
These are real
assignments IÕve created and given to my students over the years. Solutions are available by contacting me.
Topic 1 The Celestial Sphere
The Angular Size of a Distant Object
On his very first attempt at
astrophotography, Jeff Field of New Hampshire took the photo below which I have
reproduced from the October 2000 edition of Sky and Telescope magazine
with permission both from the photographer and from the magazine. The picture shows a Lockheed-Martin C-5
ÒGalaxyÓ transport aircraft (on the right) being refueled in mid-air against
the backdrop of the waxing crescent Moon.
The Lockheed-Martin Corporation
web site gives the true length of a C-5 as 75.53 meters. See the C-5 spec sheet at: http://www.lmaeronautics.com/products/airmobility/c5/specs.html
The goal here is to determine the
distance (in kilometers) between the C-5 aircraft and the photographer.
Hints: You will need a ruler marked out in millimeters for this
question. Recall that the angular
diameter of the full Moon is about 0.5 degrees. Use this information to determine a Òscale factorÓ in
millimeters per degree for the photograph first. You do not need to know the true distance to the Moon
or the true size of the Moon.
Assume that, even though this is not a first quarter Moon, the distance
between the ÒhornsÓ of the crescent is a good estimate of the MoonÕs diameter
on the photograph.
Topic 2 Seasons and
the Motion of the Sun
Using the Solar Motion Demonstrator
The exercise given below is just
one of many possible ways students can use the SMD to help them appreciate the
seasonal changes occurring on the different parts of the Earth throughout the
year. It is easy to vary the
particular locations. I try to
choose three or four that represent low-, mid-, and high-latitudes so the students
can see the a wide variation in their answers. You can even make the exercise more challenging by throwing
in a southern-hemisphere city
To use the Solar Motion
Demonstrator, pivot the green compass disk along the north-south axis so that
the right hand side of the disk moves away from you through 90 degrees. Line up the slot in the compass disk
with the edge of the frame where it is labeled "Latitude". Slip the slot in the compass disk over
the frame and align it with the latitude of the location of interest. The compass disk must be perpendicular
to the frame. The head of the
metal fastener represents the Sun.
Slide the "Sun" along the outer rim of the frame to the
approximate day and month desired.
The edge of the compass disk
represents the visible horizon for some imaginary person standing at the black
dot in the center of the disk. To
see the path the Sun makes across the sky for that particular latitude and time
of year, swing the month portion of the frame completely from the
"East" to the "West" as shown on the compass disk. The perimeter of the compass disk is
marked in 10 degree increments.
You can read the direction to the point on the horizon where the Sun
sets (or rises) directly from the compass disk. For example, if you are at 40 degrees latitude and it is
late June, the Sun will set about 30 degrees to the north of west. Comparing the location of the sunrise
and sunset points at different times of the year is just one of the many things
you can do! Note: you
will also need a protractor along with the SMD to measure noontime altitude
1. Complete
Table 1 on the next page by answering the following questions.
a) Use an atlas of the
world to determine the latitude, longitude and country of the North American
city of Tuktoyaktuk. For an
observer in Tuktoyaktuk, determine at what directions along the horizon the Sun
rises and sets for the various days of the year given in the table. State your sunrise answers as "X
degrees north (or south) of due East"; state your sunset answers as
"X degrees north (or south) of due West". Use a protractor to help you estimate what is the maximum
angle above the southern horizon
reached by the noontime Sun on each of these days. Record all of your answers in the table.
b) Repeat for an
observer in the European city of Nice.
c) Repeat for an
observer in the African city of Dakar.
d) Write a paragraph
discussing your results for Tuktoyaktuk, Nice and Dakar. Do your answers make sense for what you
know or have read/seen about the climate conditions at each location? Consider things like climate, the
lengths of daylight and nighttime, and the noontime altitude of the Sun.
e) Does the term
Òmidnight sunÓ have any connection to any of these places? Which one? How and why?
Table 1: Data for Tuktoyaktuk, Nice and Dakar
Tuktoyaktuk: __________________ latitude __________________ longitude __________________ country
Nice: __________________ latitude __________________ longitude __________________ country
Dakar: __________________ latitude __________________ longitude __________________ country
Reference for above data:
City Feb
1 Apr
15 Jun
20
Rise Max
Noon Set Rise Max
Noon Set Rise Max
Noon Set
Altitude Altitude Altitude
Tuktoyaktuk
Nice
Dakar
City Sept
1 Nov
15 Dec
20
Rise Max
Noon Set Rise Max
Noon Set Rise Max
Noon Set
Altitude Altitude Altitude
Tuktoyaktuk
Nice
Dakar
Topic 10 Small Solar System
Bodies
Using Lowell Observatory Near-Earth Object Search (LONEOS) Data
Attached is a series of three
photographs of the night sky taken with the 21-inch telescope of the LOwell Near-Earth Object
Search in Flagstaff,
Arizona. Compare the photographs
carefully. Somewhere in the
photographed patch of sky is a near-Earth object (NEO) called 1999CW7, an
asteroid with an orbit that could bring it very close to (or in contact with!)
the Earth. The only way such an
object can be discovered is if someone notices its movement against the
background stars. So, one
photograph alone is not sufficientÑyou need to look at a series of pictures
taken over a span of time. The
purpose of the LONEOS survey is to find as many of these objects as possible
and figure out their orbital characteristics so we can keep track of them and
predict their movements. For more
information about the project and the telescope, check out the LONEOS web page
at http://asteroid.lowell.edu/asteroid/loneos/loneos_disc.html
Locate and carefully circle 1999CW7 on each photograph. Place a transparent grid over each of
the photos one by one. For each
photo, use a marker to carefully record the position of the object. Use a ruler to very accurately measure
the distance in millimeters between the initial and final positions of the
NEO. If the photographs have a
scale of 2.81 seconds of arc per millimeter, how far has 1999CW7 moved on the
sky in the time span between the first and last photos? With what angular speed (in seconds of
arc per minute) is it apparently moving across the sky? If this asteroid takes about 1.5 years to orbit the Sun,
what must be its average distance from the Sun (hint: remember Kepler's third law)?
Picture #1 -- Taken on Feb 13, 1999 at 08h 56m 40s
(photograph courtesy of Lowell
Observatory)
Picture #2 -- Taken on Feb
13, 1999 at 09h 29m 45s
(photograph courtesy of Lowell
Observatory)
Picture #3 -- Taken
on February 13, 1999 at 10h
02m 50s
(photograph courtesy of Lowell Observatory)
Topic 10 Small Solar System
Bodies
A Near-Earth Passage of the Asteroid Toutatis
Let's look at NEO's from another perspective. In the recent past, a 5-mile wide
asteroid named Toutatis made a very close pass by the Earth--it came almost as
close to the Earth as the Moon does!
And on the cosmic scale, that's CLOSE!
The object of this exercise is to see if you can determine
exactly when that close passage occurred.
You will need a ruler and a transparent protractor. Attached is a view of the inner Solar
System showing the orbits of the Earth and other well-known objects. You know that the distance from the Sun
to the Earth is 1 Astronomical Unit; measure this distance in millimeters on
the diagram and record this number on the line below. Now you know how many millimeters are necessary to make 1 AU
on this diagram.
Below is a table of distance and angle information for
Toutatis for a series of days; you are going to use this information to plot
part of the orbit of this asteroid to see when it came closest to Earth. For each day, convert the distance
between Toutatis and the Sun from AU's to millimeters using your conversion
number and write these distances into the table.
Center your protractor on the Sun with the zero degree line
horizontal as indicated. For each
day in the table, locate its angle along the edge of the protractor and make a
small tickmark on the chart. Then
draw a faint line from the Sun along your tickmark to represent the distance of
Toutatis on that day. Use an "x"
to mark the location of Toutatis on that day. Label the x with the day number. Draw a smooth (i.e not bumpy!) curved line through all
of the x's. Look at the locations
where the orbit of Toutatis crosses the orbit of the Earth. Are there any days when the Earth and
Toutatis are in the same place at the same time?
1 Astronomical Unit =
_______________ millimeters
Day Number Date Angle Distance
in AU Distance
in mm
|
1
|
Sept 21, 1992
|
339o
|
1.18
|
|
|
2
|
Oct 1, 1992
|
349o
|
1.09
|
|
|
3
|
Oct 10, 1992
|
359o
|
1.02
|
|
|
4
|
Oct 20, 1992
|
11o
|
0.96
|
|
|
5
|
Oct 30, 1992
|
22o
|
0.96
|
|
|
6
|
Nov 10, 1992
|
38o
|
0.89
|
|
|
7
|
Nov 20, 1992
|
51o
|
0.91
|
|
|
8
|
Nov 30, 1992
|
66o
|
0.92
|
|
|
9
|
Dec 9, 1992
|
80o
|
0.98
|
|
|
10
|
Dec 19, 1992
|
92o
|
1.03
|
|
