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# good numerical solution for LDA transformation

I'm computing an LDA (linear discriminant analysis) transform, for an application I'm working on, and I've been following these notes (starting at page 36, especially slide 47 in green).

I'm doing this in Python (with numpy and scipy), and this is what I have come up with:

``````import numpy as np
from scipy.linalg import sqrtm
...
sw_inv_sqrt = np.linalg.inv(sqrtm(self.sigma_within))
self.d, self.v = np.linalg.eig(
np.dot(
np.dot(sw_inv_sqrt, self.sigma_between),
sw_inv_sqrt
))
self.v = np.dot(sw_inv_sqrt, self.v)
``````

I know that this implementation is correct as I have compared it to others. My concern is whether this is good solution in the numerical sense. In comparing my solution to others, they match only to about 6 decimal places. Is there a better way to do this numerically?

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This is in essence a mathematical question -- you are asking for a numerical method, not for its implementation. You might be better off asking on math.stackexchange.com. – Sven Marnach Dec 12 '10 at 18:05
Do you actually need more than 6 decimal places precision ? (I'd consider that pretty good actually). Are the other solutions you refer to also implemented in python ? Why do you suspect that the others' solutions are numerically better than yours (as far as I remember is this the standard way to calculate the projection vector of Fisher's linear discriminant analysis (en.wikipedia.org/wiki/Linear_discriminant_analysis) ? You could also ask on stats.stackexchange.com . – Andre Holzner Dec 12 '10 at 18:15
@Sven: I don't necessarily agree. Implementation details may introduce roundoff error, which is different from truncation error which is by essence mathematical. Moreover, with all the respect I owe to the folks at math.stackexchange, I think there are better numericists here than there. – Alexandre C. Dec 12 '10 at 18:18

Try `eigh` instead of `eig`. Since Sigma^{-1/2} B_0 Sigma^{1/2} is symmetric, use an adapted routine.