Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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]

enter image description here

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]

enter image description here

Errr ... Why?

share|improve this question
    
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

3 Answers 3

up vote 4 down vote accepted

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.

share|improve this answer
    
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.

share|improve this answer
    
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
1  
@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".

share|improve this answer
    
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

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.