This activity was about students making data observations, analyzing the data locally and then sharing their results with one another.
OBJECTIVE:
To encourage students to observe the quality of the night sky and to
determine the number of stars that can be seen from their local area.
ENGAGE:
Ask students how many stars there are outside at night. Accept all
estimates and record them on the chalkboard. Ask how they could go
beyond guesses and estimates. Tell students that they are going to
devise a way to count the stars in the sky.
EXPLORE/EXPLAIN:
Ask students to explain the phrase "Twinkle, Twinkle, Little Star".
Ask them what "twinkling" means. Explain to students that only stars
twinkle--the moon and planets do not. As a group, make the predictions
as suggested on the activity sheet below. Pick a
time for students to make night-time observations of stars.
MATERIALS
EXPAND
Plan a time for students to take a "Star Census". Review with students
how to do the counting. If possible, it would be interesting to have
students make these observations in different locations (near a city
or out in the country) and at different times (when there's a bright
moon and when there's no moon). For younger students, you can use
fewer observations. Just remember that each observation represents
1/144th of the sky. If students make only 6 observations, they would
multiply the total number of stars observed by 24 (which is 144
divided by 6).
PROCEDURE
Have your students try this experiment (at night at the agreed upon time)
to measure the number of stars you can see.
One by one, face in each of the 4 compass directions (North, South, East and West).
Hold the tube 3/4 of the way up from the horizon in each direction
and count the number of stars seen through the tube. Hold the tube
half-way up from the horizon and repeat the count. Repeat the
procedure again with the tube pointed a third of the way up. Repeat
observations for the other directions.
(To determine 3/4, 1/2 and 1/3, students can either use a protractor or
they can simply estimate the angle)
ONLINE CONNECTION
There were two parts to the online connection
1) a quick look at some simple data observed between March 15 - 22
2) a more detailed, longer time frame collaboration
Part 1:
For the quick look part, students counted the number of stars they saw as
detailed above. As a class, come up with one number which is a good
average of the count in your area. (Don't forget to multiply by 12 to
estimate the total number of stars in the whole sky).
Classrooms then sent that one number,
along with their city, state (and country if not US), latitude and
longitude to us.
Part 2:
We hope that teachers will also work with their students to prepare reports
from their observations which better reflect the complexities of the task.
For example, how do the following factors effect the numbers:
- weather
- proximity to surface lighting
- time of night that the observations were made
- size of the moon (if you take make observations over time)
- etc, etc
Hopefully the class can together produce a report that includes the original data and the conclusions that were derived from analyzing this data.
As an additional activity, classes examined other reports and
1) got ideas for improving their original report
2) derived new meaning by comparing data from other locations
(for example, students may learn that students in the mountains see more
stars then those closer to sea level).
The format of these reports was up to the individual teachers. Graphs and other visuals would make reports more attractive to others, if your class can find something meaningful to graph. Charts of the real data collected might be interesting to some. Students were encouraged to be as creative as they could, since their audience would be other engaged classrooms across the county and the world.
ACTIVITIES SHEET:
Have you ever wondered what makes a star twinkle? On the next clear night look at a bright star.
A star is a point of light. It is so far away that even the largest telescope cannot show the star's disk. The atmosphere changing between the star and your eye causes starlight to twinkle.
Make these predictions about twinkling:
Share your data with students in other locations to answer the remaining questions.
"Seeing" is the term astronomers use to describe the steadiness of images. "Seeing" is best when the twinkling is least. When the seeing is good, astronomers can collect better data about the brightness and color of distant stars and galaxies.