I have an object w/ and orientation and the rotational rates about each of the body axis. I need to find a smooth transition from this state to a second state with a different set of rates. Additionally, I have constraints on how fast I can rotate/accelerate about each of the axis.
I have explored Quaternion slerp's, and while I can use them to smoothly interpolate between the states, I don't see an easy way to get the rate matching into it.
This feels like an exercise in differential equations and path planning, but I'm not sure exactly how to formulate the problem so that the algorithms that are out there can work on it.
Any suggestions for algorithms that can help solve this and/or tips on formulating the problem to work with those algorithms would be greatly appreciated.
[Edit - here is an example of the type of problem I'm working on]
Think of a gunner on a helicopter that needs to track a target as the helicopter is flying. For the sake of argument, he needs to be on the target from the time it rises over the horizon to the time it is no longer in view. The relative rate of this target is not constant, but I assume that through the aggregation of several 'rate matching' maneuvers I can approximate this tracking fairly well. I can calculate the gun orientation and tracking rates required at any point, it's just generating a profile from some discrete orientations and rates that is stumping me.