# Uncertainty propagation formula in mathematica

I'm trying to write a short piece of code that will perform propagation of errors. So far, I can get Mathematica to generate the formula for the error delta_f in a function f(x1,x2,...,xi,...,xn) with errors dx1,dx2,...,dxi,...dxn:

``````fError[f_, xi__, dxi__] :=
Sum[(D[f[xi], xi[[i]]]*dxi[[i]])^2, {i, 1, Length[xi]}]^(1/2)
``````

where fError requires that the input function f has all of its variables surrounded by {...}. For example,

``````d[{mv_, Mv_, Av_}] := 10^(1/5 (mv - Mv + 5 - Av))
FullSimplify[fError[d, {mv, Mv, Av}, {dmv, dMv, dAv}]]
``````

returns

``````2 Sqrt[10^(-(2/5) (Av - mv + Mv)) (dAv^2 + dmv^2 + dMv^2)] Log[10]
``````

My question is, how can I evaluate this? Ideally I would like to modify fError to something like:

``````fError[f_, xi__, nxi__, dxi__]
``````

where nxi is the list of actual values of xi (separated since setting the xi's to their numerical values will destroy the differentiation step above.) This function should find the general formula for the error delta_f and then evaluate it numerically, if possible. I think the solution should be as simple as a Hold[] or With[] or something like that, but I can't seem to get it.

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This may prove useful. –  rcollyer Mar 2 '13 at 4:04
@rcollyer Those all seem a little more advanced than what I need. I'm really just looking for an elegant, one- or two-line solution that I can adapt to various calculations. I never have to deal with correlated errors, either. I have found, though, that if I just call fError[f,xi,dxi]/.{x1->nx1,...}, it works. That's good enough for my purposes. –  user1748343 Mar 2 '13 at 7:37