This example shows how to fit a kernel probability distribution object to sample data.
Step 1. Load sample data.
Load the sample data.
This data contains miles per gallon (
measurements for different makes and models of cars, grouped by country
of origin (
Origin), model year (
and other vehicle characteristics.
Step 2. Fit a kernel distribution object.
fitdist to fit a kernel probability distribution
object to the miles per gallon (
MPG) data for all
makes of cars.
pd = fitdist(MPG,'Kernel')
pd = KernelDistribution Kernel = normal Bandwidth = 4.11428 Support = unbounded
This creates a
fitdist uses a normal kernel smoothing
function and chooses an optimal bandwidth for estimating normal densities,
unless you specify otherwise. You can access information about the
fit and perform further calculations using the related object functions.
Step 3. Compute descriptive statistics.
Compute the mean, median, and standard deviation of the fitted kernel distribution.
m = mean(pd) med = median(pd) s = std(pd)
m = 23.7181 med = 23.4841 s = 8.9896
Step 4. Compute and plot the pdf.
Compute and plot the pdf of the fitted kernel distribution.
figure; x = 0:1:60; y = pdf(pd,x); plot(x,y,'LineWidth',2); title('Miles per Gallon'); xlabel('MPG');
The plot shows the pdf of the kernel distribution fit to the
across all makes of cars. The distribution is smooth and fairly symmetrical,
although it is slightly skewed with a heavier right tail.
Step 5. Generate random numbers.
Generate a vector of random numbers from the fitted kernel distribution.
rng('default') % For reproducibility r = random(pd,1000,1); figure; hist(r); set(get(gca,'Children'),'FaceColor',[.8 .8 1]); hold on; y = y*5000; % Scale pdf to overlay on histogram plot(x,y,'LineWidth',2); title('Random Numbers Generated From Distribution'); hold off;
The histogram has a similar shape to the pdf plot because the random numbers generate from the nonparametric kernel distribution fit to the sample data.