There's an alternate concept for rotations called a rotor that is just as capable as the quaternion concept but does not require reasoning in higher dimensions: http://marctenbosch.com/quaternions/
That's fascinating. Thanks for the pointer.
> Signed multiplication and division use an internal flag called F1 to keep track of the sign. The F1 flag is toggled by microcode through the CF1 (Complement F1) micro-instruction. The F1 flag is implemented with a…
I remember being excited about MNG, but finding the open-source libmng a pain to use. It was all based around callbacks with the library driving the animation cycle. Not a great fit if you were interested in using MNG…
It's meant to be breadboard-compatible, and breadboard pin sockets are normally spaced at 0.1 inch. You can see in the first schematic that it's 0.9" by 2.0", which gives you 9x20 hole positions.
There's an alternate concept for rotations called a rotor that is just as capable as the quaternion concept but does not require reasoning in higher dimensions: http://marctenbosch.com/quaternions/
That's fascinating. Thanks for the pointer.
> Signed multiplication and division use an internal flag called F1 to keep track of the sign. The F1 flag is toggled by microcode through the CF1 (Complement F1) micro-instruction. The F1 flag is implemented with a…
I remember being excited about MNG, but finding the open-source libmng a pain to use. It was all based around callbacks with the library driving the animation cycle. Not a great fit if you were interested in using MNG…
It's meant to be breadboard-compatible, and breadboard pin sockets are normally spaced at 0.1 inch. You can see in the first schematic that it's 0.9" by 2.0", which gives you 9x20 hole positions.