I solve some very large systems of ODEs (somewhere in the range of 2,000 to 10,000 variables) and I need to make quick decisions about the output. Let's call the evolution variable `t`

and a vector of solution variables as `x`

. The solutions can look like:

`a * exp(-b * t)`

, where`a << 1`

and`b > 0`

. This is not interesting. So, it starts at some small value(s) and basically decay(s) to 0. This one is easy to spot.`c * ((tanh(b * t) + 1) / 2)`

, where`-1 < c < 1`

and`b > 0`

. So, it starts at around 0 and then evolves into something between`-1`

and`+1`

.- Something, which looks like a very skewed
`c * sin(b(t) * t)`

, where`-1 < c < 1`

and`b(t)`

is a manifestation of the fact that the solution is non-linear.

Let’s say that I sample around 1,000 (or any other number) of some aggregate results on the way and I need to distinguish between 2 and 3. After all, it is obvious when you look at the chart!

However, it is often the case that the solution may stay around zero for a good while and then starts to deviate into #2 or #3 after a while. So, whatever happens later in “time” should have more weight than whatever happens at the beginning. So, basically, I need a number or two to “tell” that a solution is `tanh`

-like or `sin`

-like and, obviously, there might be something in between!

What would be the appropriate algorithm for that? Thanks a lot!

`c.(tanh(b.t) + 1)/2`

has`y = c`

as an asymptote for`t > 0`

. For a given (t), the distance to the aymptote is:`c/(exp(2.b.t) + 1)`

(double check!). So a function that evolves to look like (2) should become increasingly 'flat', after the initial transients have decayed. – Brett Hale Jan 17 at 4:21