Content Materials
Linear Motion – Position vs. Time
Real World Data Collection and Analysis
Your next task is to locate a satellite orbiting the earth, collect its motion data, and model its motion using a spread sheet in addition to the other representational tools you’ve been exploring.
Go to one of these sites and record the satellite’s latitude, longitude, altitude, and time for a period of 5 minutes (both pages automatically update every minute)
Hubble Space Telescope
International Space Station
Here’s an example of what the Space Station page looks like:
Tracking / Sighting / OtherJ-Track / J-Track 3D / Station / Shuttle / More / J-Pass / J-Pass E-Mail / FAQ / Links
16 Jun 2004 19:35 UTC / Current Station Location
Latitude
(Degrees) / Longitude
(Degrees) / Altitude
(Kilometers)
-12.6 / 118.3 / 363.1
Latest Science News
Mob Rules - 6/16/2004
An experiment onboard the International Space Station is helping physicists decipher the group behavior of atoms and molecules.
· Bacterial Integrated Circuits - 6/10/2004
· The Transit of Venus: North American Viewer's Guide - 6/2/2004
· James Cook and the Transit of Venus - 5/28/2004
/
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By the way, positive latitudes are North and positive longitudes are East. So, extracting the important (for us) information from these data, here are some representative data:
Time (hr:min) / Latitude ( º ) / Longitude ( º ) / Altitude (km)17:33 / 33.9 S / 11.5 E / 367.4
17:34 / 36.5 S / 14.9 E / 368.4
17:35 / 39.0 S / 18.5 E / 369.5
17:36 / 41.2 S / 22.4 E / 370.5
17:37 / 43.1 S / 26.4 E / 371.4
Now, go to this website to figure out how far the space station traveled during each interval. By the way, these measurements are ground-based. The actual distance traveled by the station would actually be roughly 6% further.
How Far Is It?
Time(min) / Latitude
(degrees) / Longitude
(degrees) / Interval
Distance (km) / Total
Distance (km)
0 / 33.9 S / 11.5 E / 0 / 0
1 / 36.5 S / 14.9 E / 423 / 423
2 / 39.0 S / 18.5 E / 421 / 844
3 / 41.2 S / 22.4 E / 413 / 1254
4 / 43.1 S / 26.4 E / 392 / 1646
Using Microsoft Excel, here is an X-Y graph of the time and total distance data:
As you can see, the slope of this line is fairly constant, indicating that the space station moved at fairly constant speed. If we select a data point on the graph, add a trendline, and display the equation for the line, we get:
The slope of this line indicates the average speed of the International Space Station is 415 km/min. This is equivalent to roughly 7000 m/s, 15,500 mph or 4.3 mi/s of ground speed. At 370 km, the speed would be closer to 7500 m/s. We are ignoring the fact that the space station (and the Hubble) change altitude somewhat during these few minutes. However, it only changes by roughly 1%, so that’s a pretty safe assumption.
As an interesting side note, we can calculate the speed required for the space station to maintain an orbit at that altitude using the relationship where G = 6.67x10-11 N*m2/kg2, Me=6.0x1024kg, Re=6.4x106m and the altitude h=3.7x105m. This gives us a value closer to 7700 m/s, but that’s pretty close (less than 3% difference).