To address the question we start with the following toy model problem being here just a case study:

*Given two circles on a plane (its centers (c1 and c2) and radii (r1 and r2)) as well as a positive number r3, find all circles with radii = r3 (i.e all points c3 being centers of circles with radii = r3) tangent (externally and internally) to given two circles.*

In general, depending on `Circle[c1,r1], Circle[c2,r2] and r3`

there are 0,1,2,...8 possible solutions. A typical case with 8 solutions :

I slightly modified a neat Mathematica implementation by Jaime Rangel-Mondragon on Wolfram Demonstration Project, but its core is similar:

```
Manipulate[{c1, a, c2, b} = pts;
{r1, r2} = Map[Norm, {a - c1, b - c2}];
w = Table[
Solve[{radius[{x, y} - c1]^2 == (r + k r1)^2,
radius[{x, y} - c2]^2 == (r + l r2)^2}
] // Quiet,
{k, -1, 1, 2}, {l, -1, 1, 2}
];
w = Select[
Cases[Flatten[{{x, y}, r} /. w, 2],
{{_Real, _Real}, _Real}
],
Last[#] > 0 &
];
Graphics[
{{Opacity[0.35], EdgeForm[Thin], Gray,
Disk[c1, r1], Disk[c2, r2]},
{EdgeForm[Thick], Darker[Blue,.5],
Circle[First[#], Last[#]]& /@ w}
},
PlotRange -> 8, ImageSize -> {915, 915}
],
"None" -> {{pts, {{-3, 0}, {1, 0}, {3, 0}, {7, 0}}},
{-8, -8}, {8, 8}, Locator},
{{r, 0.3, "r3"}, 0, 8},
TrackedSymbols -> True,
Initialization :> (radius[z_] := Sqrt[z.z])
]
```

We can easily conclude that in a generic case we have an even number of solutions 0,2,4,6,8 while cases with an odd number of solutions 1,3,5,7 are exceptional - they are of zero measure in terms of control ranges. Thus changing in `Manipulate`

`c1, r1, c2, r2, r3`

one can observe that it is much more difficult to track cases with an odd number of circles.

One could modify on a basic level the above approach : solving purely symbolically equations for c3 as well as redesignig `Manipulate`

structure with an emphasis on changing number of solutions. If I'm not wrong `Solve`

can work only numerically with `Locator`

in `Manipulate`

, however here `Locator`

seems to be crucial for simplicity of controlling `c1, r1, c2, r2`

as well as for the whole implementation.

Let's state the questions, :

**1. How can we force Manipulate to track seamlessly cases with an odd number of solutions (circles) ?**

**2. Is there any way to make Solve to find exact solutions of the underlying equations?**

**( I find the answer by Daniel Lichtblau to be the best approach to the question 2, but it seems in this instance there is still an essential need for sketching of a general technique of emphasizing measure zero sets of solutions while working with Manipulate )**

**These considerations are of less importance while dealing with exact solutions**

*For example Solve[x^2 - 3 == 0, x] yields {{x -> -Sqrt[3]}, {x -> Sqrt[3]}}
while in case from the above of slightly more difficult equations extracted from Manipulate setting the following arguments :*

```
c1 = {-Sqrt[3], 0}; a = {1, 0}; c2 = {6 - Sqrt[3], 0}; b = {7, 0};
{r1, r2} = Map[ Norm, {a - c1, b - c2 }];
r = 2.0 - Sqrt[3];
```

*to :*

```
w = Table[Solve[{radius[{x, y} - {x1, y1}]^2 == (r + k r1)^2,
radius[{x, y} - {x2, y2}]^2 == (r + l r2)^2}],
{k, -1, 1, 2}, {l, -1, 1, 2}];
w = Select[ Cases[ Flatten[ {{x, y}, r} /. w, 2], {{_Real, _Real}, _Real}],
Last[#] > 0 &]
```

*we get two solutions :*

```
{{{1.26795, -3.38871*10^-8}, 0.267949}, {{1.26795, 3.38871*10^-8}, 0.267949}}
```

*similarly under the same arguments and equations, putting :*

```
r = 2 - Sqrt[3];
```

*we get no solutions :* `{}`

*but in fact there is exactly one solution which we would like to emphasize:*

```
{ {3 - Sqrt[3], 0 }, 2 - Sqrt[3] }
```

In fact, passing to `Graphics`

such a small difference between two different solutions and the uniqe one is indistinguishable, however working with `Manipulate`

we cannot track carefully with a desired accuracy merging of two circles and usually the last observed configuration when lowering `r3`

before vanishing all solutions (reminding so-called structural instability) looks like this :

`Manipulate`

is rather a powerful tool, not only a toy, and its mastering could be very useful. The considered issues when appearing in a serious research are frequently critical, for example: in studying solutions of nonlinear differential equations, occurence of singularities in its solutions, qualitative behavior of dynamical systems, bifurcations, phenomena in Catastrophe theory and so on.

`r3`

that allow for a circle to be centered on the line of symmetry, so you could check for those directly. – David Z Dec 11 '11 at 8:28`Manipulate`

and`Solve`

(and/or`DSolve`

,`NDSolve`

etc.) - how to control qualitative behavior of systems of (differential or polynomial etc) equations in order to not overlook crucial solutions. – Artes Dec 11 '11 at 8:58`Manipulate`

by pressing Alt while dragging the controls (or Alt+Ctrl for even finer control). Note that this works on OS X at least; for a different OS you might have to use different modifier keys. This would allow you to get a better approximation of the critical points. – Heike Dec 12 '11 at 12:18