# Orthogonalize[ ] working as expected only when applied twice

Applying `Orthogonalize[]` once:

``````v1 = PolyhedronData["Dodecahedron", "VertexCoordinates"][[1]];
Graphics3D[Line[{{0, 0, 0}, #}] & /@
Orthogonalize[{a, b, c} /.
FindInstance[{a, b, c}.v1 == 0 && (Chop@a != 0.||Chop@b != 0.||Chop@c != 0.),
{a, b, c}, Reals, 4]], Boxed -> False]
``````

And now twice:

``````Graphics3D[Line[{{0, 0, 0}, #}] & /@
Orthogonalize@Orthogonalize[{a, b, c} /.
FindInstance[{a, b, c}.v1 == 0 && (Chop@a != 0.||Chop@b != 0.||Chop@c != 0.),
{a, b, c}, Reals, 4]], Boxed -> False]
``````

Errr ... Why?

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So, Szabolcs gets a congrats, but I don't?!? :D –  rcollyer Nov 17 '11 at 16:35
Hmmm, ran a recalc, and it didn't work out like I expected. Below 5k, again. –  rcollyer Nov 17 '11 at 20:49
@rcollyer Congrats!! :D I was out dining ;-) –  Szabolcs Nov 17 '11 at 21:13
@Szabolcs, thanks. Honestly, I was just poking fun at him. –  rcollyer Nov 17 '11 at 21:15

I also assumed it would be a numerical error, but didn't quite understand why, so I tried to implement Gram-Schmidt orthogonalization myself, hoping to understand the problem on the way:

``````(* projects onto a unit vector *)
proj[u_][v_] := (u.v) u

Clear[gm, gramSchmidt]

gm[finished_, {next_, rest___}] :=
With[{v = next - Plus @@ Through[(proj /@ finished)[next]]},
gm[Append[finished, Normalize@Chop[v]], {rest}]
]

gm[finished_, {}] := finished

gramSchmidt[vectors_] := gm[{}, vectors]
``````

(Included for illustration only, I simply couldn't quite figure out what's going on before I reimplemented it myself.)

A critical step here, which I didn't realize before, is deciding whether a vector we get is zero or not before the normalization step (see `Chop` in my code). Otherwise we might get something tiny, possibly a mere numerical error, which is then normalized back into a large value.

This seems to be controlled by the `Tolerance` option of `Orthogonalize`, and indeed, raising the tolerance, and forcing it to discard tiny vectors fixes the problem you describe. `Orthogonalize[ ... , Tolerance -> 1*^-10]` works in a single step.

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I think you're right. Using your code with and without `Chop` in `FindInstance` gives me two planes whose normals differ by a sign. I get the same thing using `Orthogonalize` with `Tolerance -> 10^-10`. –  rcollyer Nov 17 '11 at 13:37

I think the first result is due to numerical error, taking

``````sys = {a,b,c}/.FindInstance[
{a, b, c}.v1 == 0 && (Chop@a != 0. || Chop@b != 0. || Chop@c !=0.),
{a, b, c}, Reals, 4];
``````

then `MatrixRank@sys` returns 2, therefor the system itself is only two dimensional. To me, this implies that the first instance of `Orthogonalize` is generating a numerical error, and the second instance is using the out of plane error to give you your three vectors. Removing the `Chop` conditions fixes this,

``````Orthogonalize[{a, b, c} /.
N@FindInstance[{a, b, c}.v1 == 0,{a, b, c}, Reals, 4]]
``````

where `N` is necessary to get rid of the `Root` terms that appear. This gives you a two-dimensional system, but you can get a third by taking the cross product.

Edit: Here's further evidence that its numerical error due to `Chop`.

With `Chop`, `FindInstance` gives me

``````{{64., 3.6, 335.108}, {-67., -4.3, -350.817}, {0, 176., 0},
{-2., -4.3, -10.4721}}
``````

Without `Chop`, I get

``````{{-16.8, 3.9, -87.9659}, {6.6, -1.7, 34.558}, {13.4, -4.3, 70.1633},
{19.9, -4.3, 104.198}}
``````

which is a significant difference between the two.

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This can also be cured by applying `Normalize /@` before orthogonalization –  Szabolcs Nov 17 '11 at 12:59
@Szabolcs, at least on my system, it doesn't, and I wouldn't expect it to as the numerical errors remain. –  rcollyer Nov 17 '11 at 13:02
I'm on 32-bit Windows, 8.0.4, `Orthogonalize[Normalize /@ (...)]` fixes it here. The vectors I get from FindInstance are the same as on your machine. –  Szabolcs Nov 17 '11 at 13:16
@Szabolcs, I think I see what the misunderstanding was. Yes, using `Normalize` first eliminates the need for the second `Orthogonalize` on my machine (v.7.0.1 on MacOS), also. But, it still returns 3 non-zero vectors, which is the error I was referring to. There should be only 2 non-zero vectors, but `Chop` introduces enough numerical error to give an erroneous out-of-plane term which `Orthogonalize` picks up on. –  rcollyer Nov 17 '11 at 13:23
@rcollyer Hey! Congrats! :D –  belisarius Nov 17 '11 at 22:46

Perhaps it is a characteristic of the default GramSchmidt method?

Try: `Method -> "Reorthogonalization"` or `Method -> "Householder"`.

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The default is actually "ModifiedGramSchmidt". Just an observation after playing with it. –  Szabolcs Nov 17 '11 at 12:40
I think it is strictly a numerical error due to his use of `Chop`, as without it, you get only 2 non-zero vectors. –  rcollyer Nov 17 '11 at 12:40