Configuration: liquidSVM model configuration parameters.

display

This parameter determines the amount of output of you see at the screen: The larger its value is, the more you see. This can help as a progress indication.

Parameters for regression (least-squares, quantile, and expectile)

clipping

This parameter determines whether the decision functions should be clipped at the specified value. The value clipping = -1.0 leads to an adaptive clipping value, whereas clipping = 0 disables clipping.

Parameter for multiclass classification determine the multiclass strategy: mc-type=0 : AvA with hinge loss. mc-type=1 : OvA with least squares loss. mc-type=2 : OvA with hinge loss. mc-type=3 : AvA with least squares loss.

Parameters for Neyman-Pearson Learning

class

The class, the constraint is enforced on.

constraint

The constraint on the false alarm rate. The script actually considers a couple of values around the value of constraint to give the user an informed choice.

For Support Vector Machines two hyperparameters need to be determined:

• gamma the bandwith of the kernel

• lambda has to be chosen such that neither over- nor underfitting happen. lambda values are the classical regularization parameter in front of the norm term.

liquidSVM has a built-in a cross-validation scheme to calculate validation errors for many values of these hyperparameters and then to choose the best pair. Since there are two parameters this means we consider a two-dimensional grid.

For both parameters either specific values can be given or a geometrically spaced grid can be specified.

gamma_steps, min_gamma, max_gamma

specifies in the interval between min_gamma and max_gamma there should be gamma_steps many values

gammas

e.g. gammas=c(0.1,1,10,100) will do these four gamma values

lambda_steps, min_lambda, max_lambda

specifies in the interval between min_lambda and max_lambda there should be lambda_steps many values

lambdas

e.g. lambdas=c(0.1,1,10,100) will do these four lambda values

c_values

the classical term in front of the empirical error term, e.g. c_values=c(0.1,1,10,100) will do these four cost values (basically inverse of lambdas)

Note the min and max values are scaled according the the number of samples, the dimensionality of the data sets, the number of folds used, and the estimated diameter of the data set.

Using grid_choice allows for some general choices of these parameters

Using negative values of grid_choice we create a grid with listed gamma and lambda values:

An adaptive grid search can be activated. The higher the values of MAX_LAMBDA_INCREASES and MAX_NUMBER_OF_WORSE_GAMMAS are set the more conservative the search strategy is. The values can be freely modified.

A major issue with SVMs is that for larger sample sizes the kernel matrix does not fit into the memory any more. Classically this gives an upper limit for the class of problems that traditional SVMs can handle without significant runtime increase. Furthermore also the time complexity is at least \(O(n^2)\).

liquidSVM implements two major concepts to circumvent these issues. One is random chunks which is known well in the literature. However we prefer the new alternative of splitting the space into spatial cells and use local SVMs on every cell.

If you specify useCells=TRUE then the sample space \(X\) gets partitioned into a number of cells. The training is done first for cell 1 then for cell 2 and so on. Now, to predict the label for a value \(x\in X\) liquidSVM first finds out to which cell this \(x\) belongs and then uses the SVM of that cell to predict a label for it.

If you run into memory issues turn cells on: \code{useCells=TRUE}

This is quite performant, since the complexity in both time and memore are both \(O(\mbox{CELLSIZE} \times n)\) and this holds both for training as well as testing! It also can be shown that the quality of the solution is comparable, at least for moderate dimensions.

The cells can be configured using the partition_choice:

1. This gives a partition into random chunks of size 2000

   VORONOI=c(1, 2000)

2. This gives a partition into 10 random chunks

   VORONOI=c(2, 10)

3. This gives a Voronoi partition into cells with radius not larger than 1.0. For its creation a subsample containing at most 50.000 samples is used.

   VORONOI=c(3, 1.0, 50000)

4. This gives a Voronoi partition into cells with at most 2000 samples (approximately). For its creation a subsample containing at most 50.000 samples is used. A shrinking heuristic is used to reduce the number of cells.

   VORONOI=c(4, 2000, 1, 50000)

5. This gives a overlapping regions with at most 2000 samples (approximately). For its creation a subsample containing at most 50.000 samples is used. A stopping heuristic is used to stop the creation of regions if 0.5 * 2000 samples have not been assigned to a region, yet.

   VORONOI=c(5, 2000, 0.5, 50000, 1)

6. This splits the working sets into Voronoi like with PARTITION_TYPE=4. Unlike that case, the centers for the Voronoi partition are found by a recursive tree approach, which in many cases may be faster.

   VORONOI=c(6, 2000, 1, 50000, 2.0, 20, 4,)

The first parameter values correspond to NO_PARTITION, RANDOM_CHUNK_BY_SIZE, RANDOM_CHUNK_BY_NUMBER, VORONOI_BY_RADIUS, VORONOI_BY_SIZE, OVERLAP_BY_SIZE

• qt, ex: Here the number of considered tau-quantiles/expectiles as well as the considered tau-values are defined. You can freely change these values but notice that the list of tau-values is space-separated!

• npl, roc: Here, you define, which weighted classification problems will be considered. The choice is usually a bit tricky. Good luck ...

NPL:
WEIGHT_STEPS=10
MIN_WEIGHT=0.001
MAX_WEIGHT=0.5
GEO_WEIGHTS=1
ROC:
WEIGHT_STEPS=9
MAX_WEIGHT=0.9
MIN_WEIGHT=0.1
GEO_WEIGHTS=0

By specifying groupIds when initializing an SVM samples obtain group ids. This by default also sets FOLDS_KIND to GROUPED. If the latter is the case then samples with the same group id will be put into the same fold at cross validation. This is important if e.g. there are several patients with several measurements each.

The following parameters should only employed by experienced users and are self-explanatory for these:

KERNEL

specifies the kernel to use, at the moment either GAUSS_RBF or POISSON

RETRAIN_METHOD

After training on grids and folds there are only solutions on folds. In order to construct a global solution one can either retrain on the whole training data (SELECT_ON_ENTIRE_TRAIN_SET) or the (partial) solutions from the training are kept and combined using voting (SELECT_ON_EACH_FOLD default)

store_solutions_internally

If this is true (default in all applicable cases) then the solutions of the train phase are stored and can be just reused in the select phase. If you slowly run out of memory during the train phase maybe disable this. However then in the select phase the best models have to be trained again.

For completeness here are some values that usually get set by the learning scenario

SVM_TYPE

KERNEL_RULE, SVM_LS_2D, SVM_HINGE_2D, SVM_QUANTILE, SVM_EXPECTILE_2D, SVM_TEMPLATE

LOSS_TYPE

CLASSIFICATION_LOSS, MULTI_CLASS_LOSS, LEAST_SQUARES_LOSS, WEIGHTED_LEAST_SQUARES_LOSS, PINBALL_LOSS, TEMPLATE_LOSS

VOTE_SCENARIO

VOTE_CLASSIFICATION, VOTE_REGRESSION, VOTE_NPL

KERNEL_MEMORY_MODEL

LINE_BY_LINE, BLOCK, CACHE, EMPTY

FOLDS_KIND

BLOCKS, ALTERNATING, RANDOM, STRATIFIED, GROUPED, RANDOM_SUBSET

WS_TYPE

FULL_SET, MULTI_CLASS_ALL_VS_ALL, MULTI_CLASS_ONE_VS_ALL, BOOT_STRAP