Well, it should be possible to calculate the needed thrust as a function of vehicle mass and the latitude (can't remember what's latitude or longtitude - bear over with me if I'm wrong) required.
In an equatorial orbit, the thrust should be zero, in a "polar Jarrah orbit" the thrust should be equal to the gravity exerted on the craft.
I decided to put pencil to paper and came up with some crazy numbers. I assumed we're going to "orbit" about the artic circle. To get there I figure we'd launch into a normal orbit with an inclination of 66.5 degrees. When arriving at the northernmost part of our orbit we'd be over the artic circle. We'd then burn our engine to keep us circling over the latitude of 66.5
o N. I assumed we'd retain our original speed, thus allowing us to return to the original orbit just be shutting off the engine. I assumed an orbital radius of 6,600 km (an altitude of about 230 km).
Any object moving in a curved path has a centripetal acceleration that points in toward the center of curvature. For a body in a orbit around Earth, that acceleration is provided by gravity and is directed toward the center of Earth. For our initial orbit, the centripetal acceleration is about 9.15 m/s
2. This is less than the surface value of 9.8 m/s
2 because we're further away. The velocity of our spacecraft is 7,771 m/s.
To constantly orbit above the artic circle we must follow a curve of much smaller radius, which is 6600*cos(66.5) = 2,632 km. The centripetal acceleration needed to maintain this curved path is calculated using the equation v
2/r. Since we're maintaining our initial velocity, the required centripetal acceleration is 7771
2/2632000 = 22.95 m/s
2. The center of curvature, toward which the acceleration is directed, is located at the intersection of Earth's polar axis with the plane containing the artic circle.
The acceleration that our engine must provide to maintain this orbit is the difference between the acceleration vector of the "Jarrah orbit" and the acceleration vector of gravity. Note the use of the word
vector. We must subtract one
vector from the other, thus we must account for both magnitude and direction. We calculate the required acceleration as follows:
SQRT[ (22.95 - 9.15*cos(66.5))
2 + (0 - 9.15*sin(66.5))
2 ] = 21.05 m/s
2That's 2.15 g that must be continuously applied to maintain the Jarrah orbit. The Apollo SPS engine produced only about 0.3 to 0.8 g, depending on the mass of fuel remaining. It could also only burn for about 10 minutes before the fuel was gone.
(ETA) Let's say we placed a rocket stage on the artic circle fueled with LOX and LH2. The best mass ratio we could expect from this would be about 10. Given this configuration we'd get a delta-V of about 10,000 m/s. Providing an acceleration of 21.05 m/s
2, we'd last about 8 minutes before going kaput.
