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I asked this question yesterday but not sure if I made clear what I was looking for. Say I have two curves defined as f[x_]:=... and g[x_]:=... as shown below. I want to use Mathematica to determine the abscissa intersection of the tangent to both curves and store value for each curve separately. Perhaps this is really a trivial task, but I do appreciate the help. I am an intermediate with Mathematica but this is one I haven't been able to find a solution to elsewhere.

enter image description here

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What's the link to the question you asked yesterday? –  p.campbell Dec 21 '11 at 15:27
I deleted it, because it is was clearly ill defined and there were a lot of derogatory comments –  CaptanFunkyFresh Dec 21 '11 at 15:41
These curves fold back on themselves; I presume they are parametric? Why not include actual definitions in your question? –  Mr.Wizard Dec 21 '11 at 16:58
@Mr.Wizard I think they're freehand :) –  r.m. Dec 21 '11 at 18:23
@yoda I guessed as much myself, but if you allow such curves it is going to greatly change the answer, is it not? –  Mr.Wizard Dec 21 '11 at 18:25

2 Answers 2

up vote 10 down vote accepted
f[x_] := x^2
g[x_] := (x - 2)^2 + 3

sol = Solve[(f[x1] - g[x2])/(x1 - x2) == f'[x1] == g'[x2], {x1, x2}, Reals]

(* ==> {{x1 -> 3/4, x2 -> 11/4}} *)

eqns = FlattenAt[{f[x], g[x], f'[x1] x + g[x2] - f'[x1] x2 /. sol}, 3]; 
Plot[eqns, {x, -2, 4}, Frame -> True, Axes -> None]

enter image description here

Please note that there will be many functions f and g for which you won't find a solution in this way. In that case you will have to resort to numerical problem solving methods.

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You just need so solve a system of simultaneous equations:

The common tangent line is y = a x + b.

The common slope is a = f'(x1) = g'(x2)

The common points are a x0 + b = f(x0) and a x1 + b = g(x1).

Depending on the nature of the functions f and g this may have no, one, or many solutions.

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