Orbit
r = \frac{1}{u} = \frac{ h^2 / GM }{1 + e \cos (\theta - \theta_0)}
The above really is one of the orbital dynamics equations :-)
This image is a macro of an acrylic art piece that Mrs Mail bought a few months ago. I keep thinking about how to do a wider view of it, but wanting to do something special, yet haven't decided, so I have so far done a couple of macros, and find it quite mesmerising when looked at closely.
Watch this space.
Black and White (In Colour) Theme
Jim at Mere Mailbox
Orbit
r = \frac{1}{u} = \frac{ h^2 / GM }{1 + e \cos (\theta - \theta_0)}
The above really is one of the orbital dynamics equations :-)
This image is a macro of an acrylic art piece that Mrs Mail bought a few months ago. I keep thinking about how to do a wider view of it, but wanting to do something special, yet haven't decided, so I have so far done a couple of macros, and find it quite mesmerising when looked at closely.
Watch this space.
Black and White (In Colour) Theme
Jim at Mere Mailbox