tSVMModel

Generates an SVM-based classifier model that can be used by tPredict to classify given elements.

tSVMModel applies
the SVM algorithm to analyze feature vectors typically prepared and provided by
tModelEncoder.

It generates a binary classification model out of this analysis and
writes this model in memory or in a file system supported by this
component, such as HDFS or S3.

tSVMModel properties for Apache Spark Batch

These properties are used to configure tSVMModel running in the Spark Batch Job framework.

The Spark Batch
tSVMModel component belongs to the Machine Learning family.

This component is available in the Palette of the Studio only if you have subscribed to any Talend Platform product with Big Data or Talend Data Fabric.

Basic settings

Schema and Edit schema	A schema is a row description. It defines the number of fields (columns) to be processed and passed on to the next component. The schema is either Built-In or stored remotely in the Repository. Click Edit schema to make changes to the schema. If the current schema is of the Repository type, three options are available: View schema: choose this option to view the schema only. Change to built-in property: choose this option to change the schema to Built-in for local changes. Update repository connection: choose this option to change the schema stored in the repository and decide whether to propagate the changes to all the Jobs upon completion. If you just want to propagate the changes to the current Job, you can select No upon completion and choose this schema metadata again in the [Repository Content] window.
Label	Select the input column used to provide classification labels. The records of this column are used as the class names (Target in terms of classification) of the elements to be classified. Since a SVM model is a binary classification model, only two classes are expected, that is to say, only two distinct values are expected from this column.
Vector to process	Select the input column used to provide features. Very often, this column is the output of the feature engineering computations performed by tModelEncoder.
Save the model on file system	Select this check box to store the model in a given file system. Otherwise, the model is stored in memory. The button for browsing does not work with the Spark Local mode; if you are using the Spark Yarn or the Spark Standalone mode, ensure that you have properly configured the connection in a configuration component in the same Job, such as tHDFSConfiguration.
Step size	Enter the size (numerical value) of the initial step of the gradient descent calculation. The default value 1.0 means that the whole data set is taken. Selecting the best step size is often delicate in practice. Generally speaking, when the feature points to be analyzed are very muddled, it is recommended to increase the step size in order to cover enough number of points in each iteration; however, bear in mind that too large a step size can improperly increase the time of each iteration. On the other hand, the smaller the step size is, the more slowly the convergence occurs and a more accurate model you can expect.
Number of iterations	Enter the number of iterations you want the Job to perform to train the model.
Fraction of data to be used per iteration	Enter the fraction (expressed in decimal) of the input data to be used in each iteration to calculate the gradient. The default value 1.0 means that the whole data set is taken.
Regularization parameter	Enter the regularization number to used by the Updater function in order to avoid overfitting in learning.
Updater function	Select the function to calculate the form of the hyperplane that separates the two classes. This function updates the weights of every point in each iteration so as to perform the gradient step in a given direction to form the hyperplane. For example, in a 2-dimension space, this hyperplane can be a line or a set of lines if the points to be classified are linearly separable. The available functions are: Simple: it does not use the Regularization parameter. L1: it performs the L1 regularization. Squared L2: it performs the L2 regularization.
Gradient function	Select the loss function to calculate the margin between the hyperplane and the nearest point of either class. For further information about the loss functions available on this drop-down list, see Loss function for classification.

Advanced settings

Use feature scaling	If your training data cannot converge, select this check box to make tSVMModel reduce the condition numbers heuristically by scaling the feature data. Reducing the condition numbers can often improve the convergence rate.
Intercept	Select this check box to allow the tSVMModel to automatically calculate the intercept constants and include them in the computation. In general, intercept can guarantee that the residuals of your model have a mean of zero.
Validate data before training	Select this check box to check whether the vectors of the training data are well formatted before starting the training.

Use feature scaling

If your training data cannot converge, select this check box to make
tSVMModel reduce the condition numbers
heuristically by scaling the feature data.

Reducing the condition numbers can often improve the convergence
rate.

Intercept

Select this check box to allow the tSVMModel to automatically calculate the intercept constants
and include them in the computation.

In general, intercept can guarantee that the residuals of your model
have a mean of zero.

Validate data before
training

Select this check box to check whether the vectors of the training
data are well formatted before starting the training.

Usage

Usage rule	This component is used as an end component and requires an input link. You can accelerate the training process by adjusting the stopping conditions such as the maximum number of iterations or the step size but note that the training that stops too early could impact its accuracy.
Model evaluation	The parameters you need to set are free parameters and so their values may be provided by previous experiments, empirical guesses or the like. They do not have any optimal values applicable for all datasets. Therefore, you need to train the classifier model you are generating with different sets of parameter values until you can obtain the best confusion matrix. But note that you need to write the evaluation code yourself to rank your model with scores. You need to select the scores to be used depending on the algorithm you want to use to train your classifier model. This allows you to build the most relevant confusion matrix. For examples about how the confusion matrix is used in a Talend Job for classification, see Creating a classification model to filter spam. For a general explanation about confusion matrix, see https://en.wikipedia.org/wiki/Confusion_matrix from Wikipedia.
Spark Connection	You need to use the Spark Configuration tab in the Run view to define the connection to a given Spark cluster for the whole Job. In addition, since the Job expects its dependent jar files for execution, you must specify the directory in the file system to which these jar files are transferred so that Spark can access these files: Yarn mode: when using Google Dataproc, specify a bucket in the Google Storage staging bucket field in the Spark configuration tab; when using other distributions, use a tHDFSConfiguration component to specify the directory. Standalone mode: you need to choose the configuration component depending on the file system you are using, such as tHDFSConfiguration or tS3Configuration. This connection is effective on a per-Job basis.

Usage rule

This component is used as an end component and requires an input link.

You can accelerate the training process by adjusting the stopping conditions such as the
maximum number of iterations or the step size but note that the training
that stops too early could impact its accuracy.

Model evaluation

The parameters you need to set are free parameters and so their values may be provided by
previous experiments, empirical guesses or the like. They do not have any optimal values
applicable for all datasets.

Therefore, you need to train the classifier model you are generating with different sets
of parameter values until you can obtain the best confusion matrix. But note that you need
to write the evaluation code yourself to rank your model with scores.

You need to select the scores to be used depending on the algorithm you want to use to
train your classifier model. This allows you to build the most relevant confusion
matrix.

For examples about how the confusion matrix is used in a
Talend
Job for classification, see Creating a classification model to filter spam.

For a general explanation about confusion matrix, see https://en.wikipedia.org/wiki/Confusion_matrix from Wikipedia.

Spark Connection

You need to use the Spark Configuration tab in
the Run view to define the connection to a given
Spark cluster for the whole Job. In addition, since the Job expects its dependent jar
files for execution, you must specify the directory in the file system to which these
jar files are transferred so that Spark can access these files:

Yarn mode: when using Google
Dataproc, specify a bucket in the Google Storage staging
bucket field in the Spark
configuration tab; when using other distributions, use a
tHDFSConfiguration
component to specify the directory.
Standalone mode: you need to choose
the configuration component depending on the file system you are using, such
as tHDFSConfiguration
or tS3Configuration.

This connection is effective on a per-Job basis.

Related scenarios

No scenario is available for the Spark Batch version of this component
yet.

Document get from Talend https://help.talend.com

Thank you for watching.

Docs 6.x

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tSVMModel – Docs for ESB 6.x