The KernelType policy in mlpack
Kernel methods make up a large class of machine learning techniques. Each of these methods is characterized by its dependence on a kernel function. In rough terms, a kernel function is a general notion of similarity between two points, with its value large when objects are similar and its value small when objects are dissimilar (note that this is not the only interpretation of what a kernel is).
A kernel (or ‘Mercer kernel’) K(a, b)
takes two objects as input and returns
some sort of similarity value. The specific details and properties of kernels
are outside the scope of this documentation; for a better introduction to
kernels and kernel methods, there are numerous better resources available,
including
Eric Kim’s tutorial.
mlpack implements a number of kernel methods and, accordingly, each of these
methods allows arbitrary kernels to be used via the KernelType
template
parameter. Like the DistanceType policy, the requirements are
quite simple: a class implementing the KernelType
policy must have
- an
Evaluate()
function - a default constructor
The signature of the Evaluate()
function is straightforward:
template<typename VecTypeA, typename VecTypeB>
double Evaluate(const VecTypeA& a, const VecTypeB& b);
The function takes two vector arguments, a
and b
, and returns a double
that is the evaluation of the kernel between the two arguments. So, for a
particular kernel K
, the Evaluate()
function should return K(a, b)
.
The arguments a
and b
, of types VecTypeA
and VecTypeB
, respectively,
will be an Armadillo-like vector type (usually arma::vec
, arma::sp_vec
, or
similar). In general it should be valid to assume that VecTypeA
is a class
with the same API as arma::vec
.
Note that for kernels that do not hold any state, the Evaluate()
method can be
marked as static
.
Overall, the KernelType
template policy is quite simple (much like the
DistanceType policy). Below is an example kernel class, which
outputs 1
if the vectors are close and 0
otherwise.
class ExampleKernel
{
// Default constructor is required.
ExampleKernel() { }
// The example kernel holds no state, so we can mark Evaluate() as static.
template<typename VecTypeA, typename VecTypeB>
static double Evaluate(const VecTypeA& a, const VecTypeB& b)
{
// Get how far apart the vectors are (using the Euclidean distance).
const double distance = arma::norm(a - b);
if (distance < 0.05) // Less than 0.05 distance is "close".
return 1;
else
return 0;
}
};
Then, this kernel may be easily used inside of mlpack algorithms. For instance,
the code below runs kernel PCA (KernelPCA
) on a random dataset using the
ExampleKernel
. The results are saved to a file called results.csv
. (Note
that this is simply an example to demonstrate usage, and this example kernel
isn’t actually likely to be useful in practice.)
#include <mlpack.hpp>
#include "example_kernel.hpp" // Contains the ExampleKernel class.
using namespace mlpack;
using namespace arma;
int main()
{
// Generate the random dataset; 10 dimensions, 5000 points.
mat dataset = randu<mat>(10, 5000);
// Instantiate the KernelPCA object with the ExampleKernel kernel type.
KernelPCA<ExampleKernel> kpca;
// The dataset will be transformed using kernel PCA with the example kernel to
// contain only 2 dimensions.
kpca.Apply(dataset, 2);
// Save the results to 'results.csv'.
data::Save(dataset, "results.csv");
}
🔗 The KernelTraits
trait class
Some algorithms that use kernels can specialize if the kernel fulfills some
certain conditions. An example of a condition might be that the kernel is
shift-invariant or that the kernel is normalized. In the case of fast
max-kernel search (mlpack::fastmks::FastMKS
), the computation can be
accelerated if the kernel is normalized. For this reason, the KernelTraits
trait class exists. This allows a kernel to specify via a const static bool
when these types of conditions are satisfied. Note that a KernelTraits class
is not required, but may be helpful.
The KernelTraits
trait class is a template class that takes a KernelType
as
a parameter, and exposes const static bool
values that depend on the kernel.
Setting these values is achieved by specialization. The code below provides an
example, specializing KernelTraits
for the ExampleKernel
from earlier:
template<>
class KernelTraits<ExampleKernel>
{
public:
//! The example kernel is normalized (K(x, x) = 1 for all x).
const static bool IsNormalized = true;
};
At this time, there is only one kernel trait that is used in mlpack code:
IsNormalized
(defaults tofalse
): ifK(x, x) = 1
for allx
, then the kernel is normalized and this should be set totrue
.
🔗 List of kernels and classes that use a KernelType
mlpack comes with a number of pre-implemented and ready-to-use kernels:
GaussianKernel
: standard Gaussian/radial basis function/RBF kernelCauchyKernel
: Cauchy kernel, with longer tails than the standard Gaussian kernelCosineSimilarity
: dot-product vector similarityEpanechnikovKernel
: Epanechnikov kernel (parabolic), with zero tailsHyperbolicTangentKernel
: hyperbolic tangent kernel (not positive definite)LaplacianKernel
: Laplacian kernel/exponential kernelLinearKernel
: linear (dot-product) kernelPolynomialKernel
: arbitrary-power polynomial kernel with offsetPSpectrumStringKernel
: kernel to compute length-p subsequence match countsSphericalKernel
: spherical/uniform/rectangular window kernelTriangularKernel
: triangular kernel, with zero tails- Implement a custom kernel
These kernels (or a custom kernel) may be used in a variety of mlpack methods: