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Hi, I am doing some Kernel density estimation, with a weighted points set (ie., each sample has a weight which is not necessary one), in N dimensions. Also, these samples are just in a metric space (ie., we can define a distance between them) but nothing else. For example, we cannot determine the mean of the sample points, nor the standard deviation. The Kernel is just affected by this distance, and the weight of each sample: f(x) = 1./(sum_weights) * sum(weight_i/h * Kernel(distance(x,x_i)/h))

In this context, I am trying to find a robust estimation for the kernel bandwidth 'h', possibly spatially varying, and preferably which gives an exact reconstruction on the training dataset x_i. If necessary, we could assume that the function is relatively smooth.

I tried using the distance to the first or second nearest neighbor but it gives quite bad results. I tried with leave-one-out optimization, but I have difficulties finding a good measure to optimize for in this context in N-d, so it finds very bad estimates, especially for the training samples themselves. I cannot use the greedy estimate based on the normal assumption since I cannot compute the standard deviation. I found references using covariance matrices to get anisotropic kernels, but again, it wouldn't hold in this space...

Someone has an idea or a reference ?

Thank you very much in advance!

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  • $\begingroup$ A better place for your question would be stats.stackexchange.com $\endgroup$
    – robin girard
    Commented Aug 20, 2010 at 6:23
  • $\begingroup$ thanks, I didn't know this site. I'm trying now. :) $\endgroup$
    – WhitAngl
    Commented Aug 20, 2010 at 18:35
  • $\begingroup$ About using neighbors--although this seems like a reasonable idea, there is very little work in this direction. Luc Devroye has a few papers on this topic http://cg.scs.carleton.ca/~luc/devs.html , and you'll see that just looking at the closest is inadequate. In general, cross-validation is the standard technique. If you are interested in L1 density estimates, there is an excellent book by Devroye and Lugosi titled "Combinatorial Methods in Density Estimation". $\endgroup$
    – Matus Telgarsky
    Commented Aug 22, 2010 at 13:26

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Robin is right, you can use this site. Let me ask a question, you estimate the density by the kernel estimator (Nadaraya-Watson), your writing of the estimator is not enough correct, when I copy your source and compile it with LaTeX writing is not correct, any ways the kernel estimator of the density of a functional regressor is $$ \widehat{f}(x)= \frac{\displaystyle\sum_{i=1}^{n}K\Big(h_K^{-1}d(x,X_i)\Big)Y_i}{\displaystyle\sum_{i=1}^{n}K\Big(h_K^{-1}d(x,X_i)\Big)} . $$ where $d (.,.)$ is the metric . You can refer to Ferraty et al of Sabatier University, I think you know people there (I saw your CV). So we must choose the metric $d$, to estimate the smoothing parameter $h$, I think they found a way to choose, by cross-validation, they are obtained the optimal $h$. So before starting, I would advise you to see the work of the team probability for Laboratory Toulouse. For the robustness you can see the book of Huber (1981): Robust Statistics, it is very good, or Hambel et al (1986). Good lunk.

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