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I am trying to pre-process biological data to train a neural network and despite an extensive search and repetitive presentation of the various normalization methods I am none the wiser as to which method should be used when. In particular I have a number of input variables which are positively skewed and have been trying to establish whether there is a normalisation method that is most appropriate.

I was also worried about whether the nature of these inputs would affect performance of the network and as such have experimented with data transformations (log transformation in particular). However some inputs have many zeros but may also be small decimal values and seem to be highly affected by a log(x + 1) (or any number from 1 to 0.0000001 for that matter) with the resulting distribution failing to approach normal (either remains skewed or becomes bimodal with a sharp peak at the min value).

Is any of this relevant to neural networks? ie. should I be using specific feature transformation / normalization methods to account for the skewed data or should I just ignore it and pick a normalization method and push ahead?

Any advice on the matter would be greatly appreciated!

Thanks!

2 Answers 2

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As features in your input vector are of different nature, you should use different normalization algorithms for every feature. Network should be feeded by uniformed data on every input for better performance.

As you wrote that some data is skewed, I suppose you can run some algoritm to "normalize" it. If applying logarithm does not work, perhaps other functions and methods such as rank transforms can be tried out.

If the small decimal values do entirely occur in a specific feature, then just normalize it in specific way, so that they get transformed into your work range: either [0, 1] or [-1, +1] I suppose.

If some inputs have many zeros, consider removing them from main neural network, and create additional neural network which will operate on vectors with non-zeroed features. Alternatively, you may try to run Principal Component Analysis (for example, via Autoassociative memory network with structure N-M-N, M < N) to reduce input space dimension and so eliminate zeroed components (they will be actually taken into account in the new combined inputs somehow). BTW, new M inputs will be automatically normalized. Then you can pass new vectors to your actual worker neural network.

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This is an interesting question. Normalization is meant to keep features' values in one scale to facilitate the optimization process.

I would suggest the following:

1- Check if you need to normalize your data. If, for example, the means of the variables or features are within same scale of values, you may progress with no normalization. MSVMpack uses some normalization check condition for their SVM implementation. If, however, you need to do so, you are still advised to run the models on the data without Normalization.

2- If you know the actual maximum or minimum values of a feature, use them to normalize the feature. I think this kind of normalization would preserve the skewedness in values.

3- Try decimal value normalization with other features if applicable.

Finally, you are still advised to apply different normalization techniques and compare the MSE for evey technique including z-score which may harm the skewedness of your data.

I hope that I have answered your question and gave some support.

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  • Regarding the normalization check condition, I tried to run some dataset using MSVMPack and I got the following output: ** Columns of the data matrix show a large difference ** between their standard deviations (> 10). ** This could affect the performance of the classifier. Do you want the data to be normalized ([y]/n)?
    – soufanom
    Nov 10, 2012 at 12:11

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