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Introduction to local (nonparametric) density estimation methods

A slecture by Yu Liu

(partially based on Prof. Mireille Boutin's ECE662 lecture)

click here for PDF version


1. Introduction

This slecture introduces two local density estimation methods which are Parzen density estimation and k-nearest neighbor density estimation. Local density estimation is also referred to as non-parametric density estimation. To make things clear, let’s first look at parametric density estimation. In parametric density estimation, we can assume that there exists a density function which can be determined by a set of parameters. The set of parameters are estimated from the sample data and are later used in designing the classifier. However, in some practical situations the assumption that there exists a parametric form of the density function does not hold true. For example, it is very hard to fit a multimodal probability distribution with a simple function. In this case, we need to estimate the density function in the nonparametric way, which means that the density function is estimated locally based on a small set of neighboring samples. Because of this locality, local (nonparametric) density estimation is less accurate than parametric density estimation. In the following text the word “local” is preferred over “nonparametric.”

It is noteworthy that it is very difficult to obtain an accurate local density estimation, especially when the dimension of the feature space is high. So why do we bother using local density estimation? This is because our goal is not to get an accurate estimation, but rather to use the estimation to design a well performed classifier. The inaccuracy of local density estimation does not necessarily lead to a poor decision rule.

2. General Principle

In local density estimation the density function pn(x) can be approximated by


where vn is the volume of a small region R around point x, n is the total number of samples xi (i =1, 2…, n) drawn according to pn(x), and kn is the number of xi’s which fall into region R. The reason why pn(x) can be calculated in this way is that pn(x) does not vary much within a relatively small region, thus the probability mass of region R can be approximated by pn(x)vn, which equals kn/n.

Some examples of region R in different dimensions: i) line segment in one-dimension, ii) circle or rectangle in two-dimension, iii) sphere or cube in three-dimension, iv) hyper sphere or hypercube in d-dimension (d > 3).

Three conditions we need to pay attention to when using formula (1) are:
i) . This is because if vn is fixed, then pn(x) only represents the average probability density as n grows larger, but what we need is the point probability density, so we should have when .
ii) . This is to make sure that we do not get zero probability density.
iii) . This is to make sure that pn(x) does not diverge.

3. Parzen Density Estimation

In Parzen density estimation vn is directly determined by n while kn is a random variable which denotes the number of samples that fall into vn. Assume that the region R is a d-dimensional hypercube with its edge length hn, thus
vn = (hn)d
The equivalent conditions which meet the aforementioned three conditions are:
and
Therefore vn can be chosen as or , where h is an adjustable constant. Now that the relationship between vn and n is defined, the next step is to determine kn. To determine kn define a window function as follows:

where xi’s (i = 1, 2, …, n) are the given samples and x is the point where the density is to be estimated. Thus we have


The function is called a Parzen window function, which enables us to count the number of sample points in the hypercube with its edge length hn.

According to [2], using hypercube as the window function may lead to discontinuity in the estimation. This is due to the superimposition of sharp pulses centered at the given sample points when h is small. To overcome this shortcoming, we can consider a more general form of window function rather than the hypercube. Note that if the following two conditions are met, the estimated pn(x) is guaranteed to be proper.
and
Therefore a better choice of window function which removes discontinuity can be Gaussian window:

The estimated density is given by
(2)
Consider a one-dimension case, assume that , thus , where h is an adjustable constant. Substitute into formula (2) we have

We can see that if n equals one, pn(x) is just the window function. If n approaches infinity, pn(x) can converge to any complex form. If n is relatively small, pn(x) is very sensitive to the value of h. In general small h leads to the noise error while large h leads to the over-smoothing error, which can be illustrated by the following example.

In this experiment samples are 5000 points on 2-D plane with Gaussian distribution. The mean vector is [1 2], and the covariance matrix is [1 0; 0 1]. Choose rectangle Parzen window with , thus . Fig. 1 shows the sample distribution. Fig. 2 shows the ideal probability density distribution. Fig. 3 shows the result of Parzen density estimation.

1ly.png

Figure 1. 5000 sample points on 2-D plane with Gaussian distribution

2ly.png

Figure 2. The ideal probability density distribution

3ly.png

Figure 3. The result of Parzen density estimation

Next we change the value of hn and see how it affects the estimation. Fig. 4 shows the result of Parzen density estimation when hn is twice its initial value. Fig. 5 shows the result of Parzen density estimation when hn is its initial value divided by two. We can see that the results agree with the aforesaid property of hn.

Alumni Liaison

Ph.D. on Applied Mathematics in Aug 2007. Involved on applications of image super-resolution to electron microscopy

Francisco Blanco-Silva