The Bloke On Who Wants To Be A...
Film, Media & TV0 min ago
Having just started revising the Advanced Higher Physics course, I came upon the section on Rotationary Motion, and found myself a bit confused!
The derivations that we had been taught all involved using bodies travelling a perfectly circular path, however these same laws can apparently be applied to bodies travelling eliptical paths, such as the planetary orbits.
Why is this? I was under the impression that circles and elipses could not be interchanged with each other...am I just wrong?
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For more on marking an answer as the "Best Answer", please visit our FAQ.So...are the basic laws of rotation (like omega = omega (0) + alpha.time) only approximations of planetary motion? They all seem to rely on properties of circles, like C = 2.pi.r, but this can't be applied to elipses can it?
But basically what you're saying is, Kepler's Laws still hold for elipses? (that's the one when the period of the motion (squared) is directly proportional to the radius (cubed)?)
Sorry to drag this painful question on even more...but I've always wanted to know...why don't the planets just spiral into the sun, rather than orbit around it? My puny little mind has always just thought of it being like a satellite in orbit around earth, like "freefall", but this doesn't seem right...is it something to do with Newton's third law? *weep*
If they go in a circle it is at constant speed, (not velocity, that is a vector and the direction is always changing) and in an ellipse the speed varies - quickest near the focus and slowest furthest away.
so no, w(o) and alpha.time does not apply to ellipses - because the angular velocity is varying.
Newton was the first to realise that both situations could be explained by an inverse square law.
and in terms of the free fall of satellites,
Newton was first there too as well! He saw the apple fall and thought it would fall from the top of the house and then the top of the hill, and the highest mountain, and so why would not the moon fall in? he realised that this was because that it was in a circular motion. And so althgouht gravity was acting on the moon as well as the apple, gravity was acting to keep the moon in a circular orbit. And he thought his while he was down from cambridge in 1665 to escap e the plague and was at woolsthorpe manor in lincolnshire. He only wrote it up in 1685.
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