I have a system of (first order) ODEs with fairly expensive to compute derivatives.

However, the derivatives can be computed considerably cheaper to within given error bounds, either because the derivatives are computed from a convergent series and bounds can be placed on the maximum contribution from dropped terms, or through use of precomputed range information stored in kd-tree/octree lookup tables.

Unfortunately, I haven't been able to find any general ODE solvers which can benefit from this; they all seem to just give you coordinates and want an exact result back. (Mind you, I'm no expert on ODEs; I'm familiar with Runge-Kutta, the material in the Numerical Recipies book, LSODE and the Gnu Scientific Library's solver).

ie for all the solvers I've seen, you provide a `derivs`

callback function accepting a `t`

and an array of `x`

, and returning an array of `dx/dt`

back; but ideally I'm looking for one which gives the callback `t`

, `x`

s, *and an array of acceptable errors*, and receives `dx/dt_min`

and `dx/dt_max`

arrays back, with the derivative range guaranteed to be within the required precision. (There are probably numerous equally useful variations possible).

Any pointers to solvers which are designed with this sort of thing in mind, or alternative approaches to the problem (I can't believe I'm the first person wanting something like this) would be greatly appreciated.