I would do it like this:

First, define the catenary:

```
catenary[x_] := a*Cosh[(x - c)/a] + y
```

Now I can either find the parameters `a`

, `c`

and `y`

of this curve numerically, using `FindRoot`

:

```
Manipulate[
Module[{root},
(
root = FindRoot[
{
catenary[x1] == y1,
catenary[x2] == y2
} /. {x1 -> pt[[1, 1]], y1 -> pt[[1, 2]], x2 -> pt[[2, 1]], y2 -> pt[[2, 2]], a -> \[Alpha]},
{{y, 0}, {c, 0}}];
Show[
Plot[catenary[x] /. root /. a -> \[Alpha], {x, -2, 2},
PlotRange -> {-3, 3}, AspectRatio -> 3/2],
Graphics[{Red, Point[pt]}]]
)], {{\[Alpha], 1}, 0.001, 10}, {{pt, {{-1, 1}, {1, 1}}}, Locator}]
```

Alternatively, you could solve for the parameters exactly:

```
solution = Simplify[Solve[{catenary[x1] == y1, catenary[x2] == y2}, {y, c}]]
```

and then use this solution in the Manipulate:

```
Manipulate[
(
s = (solution /. {x1 -> pt[[1, 1]], y1 -> pt[[1, 2]],
x2 -> pt[[2, 1]], y2 -> pt[[2, 2]], a -> \[Alpha]});
s = Select[s,
Im[c /. #] == 0 &&
Abs[pt[[1, 2]] - catenary[pt[[1, 1]]] /. # /. a -> \[Alpha]] <
10^-3 &];
Show[
Plot[catenary[x] /. s /. a -> \[Alpha], {x, -2, 2},
PlotRange -> {-3, 3}, AspectRatio -> 3/2],
Graphics[{Red, Point[pt]}]]
), {{\[Alpha], 1}, 0.001, 10}, {{pt, {{-1., 1.}, {1., 0.5}}},
Locator}]
```

The `FindRoot`

version is faster and more stable, though. Result looks like this:

For completeness' sake: It's also possible to find a catenary through 3 points:

```
m = Manipulate[
Module[{root},
(
root =
FindRoot[
catenary[#[[1]]] == #[[2]] & /@ pt, {{y, 0}, {c, 0}, {a, 1}}];
Show[
Plot[catenary[x] /. root, {x, -2, 2}, PlotRange -> {-3, 3},
AspectRatio -> 3/2],
Graphics[{Red, Point[pt]}]]
)], {{pt, {{-1, 1}, {1, 1}, {0, 0}}}, Locator}]
```