If you end up extracting points from `ContourPlot`

, this is one easy way to do it:

```
points = Cases[
Normal@ContourPlot[Sin[x] Sin[y] == 1/2, {x, -3, 3}, {y, -3, 3}],
Line[pts_] -> pts,
Infinity
]
Join @@ points (* if you don't want disjoint components to be separate *)
```

**EDIT**

It appears that `ContourPlot`

does not produce very precise contours. They're of course meant for plotting and are good enough for that, but the points don't lie precisely on the contours:

```
In[78]:= Take[Join @@ points /. {x_, y_} -> Sin[x] Sin[y] - 1/2, 10]
Out[78]= {0.000163608, 0.0000781187, 0.000522698, 0.000516078,
0.000282781, 0.000659909, 0.000626086, 0.0000917416, 0.000470424,
0.0000545409}
```

We can try to come up with our own method to trace the contour, but it's a lot of trouble to do it in a general way. Here's a concept that works for smoothly varying functions that have smooth contours:

Start from some point (`pt0`

), and find the intersection with the contour along the gradient of `f`

.

Now we have a point on the contour. Move along the tangent of the contour by a fixed step (`resolution`

), then repeat from step 1.

Here's a basic implementation that only works with functions that can be differentiated symbolically:

```
rot90[{x_, y_}] := {y, -x}
step[f_, pt : {x_, y_}, pt0 : {x0_, y0_}, resolution_] :=
Module[
{grad, grad0, t, contourPoint},
grad = D[f, {pt}];
grad0 = grad /. Thread[pt -> pt0];
contourPoint =
grad0 t + pt0 /. First@FindRoot[f /. Thread[pt -> grad0 t + pt0], {t, 0}];
Sow[contourPoint];
grad = grad /. Thread[pt -> contourPoint];
contourPoint + rot90[grad] resolution
]
result = Reap[
NestList[step[Sin[x] Sin[y] - 1/2, {x, y}, #, .5] &, {1, 1}, 20]
];
ListPlot[{result[[1]], result[[-1, 1]]}, PlotStyle -> {Red, Black},
Joined -> True, AspectRatio -> Automatic, PlotMarkers -> Automatic]
```

The red points are the "starting points", while the black points are the trace of the contour.

**EDIT 2**

Perhaps it's an easier and better solution to use a similar technique to make the points that we get from `ContourPlot`

more precise. Start from the initial point, then move along the gradient until we intersect the contour.

Note that this implementation will also work with functions that can't be differentiated symbolically. Just define the function as `f[x_?NumericQ, y_?NumericQ] := ...`

if this is the case.

```
f[x_, y_] := Sin[x] Sin[y] - 1/2
refine[f_, pt0 : {x_, y_}] :=
Module[{grad, t},
grad = N[{Derivative[1, 0][f][x, y], Derivative[0, 1][f][x, y]}];
pt0 + grad*t /. FindRoot[f @@ (pt0 + grad*t), {t, 0}]
]
points = Join @@ Cases[
Normal@ContourPlot[f[x, y] == 0, {x, -3, 3}, {y, -3, 3}],
Line[pts_] -> pts,
Infinity
]
refine[f, #] & /@ points
```