Linear SVC

Linear Support Vector Machine #

Linear Support Vector Machine (Linear SVC) is an algorithm that attempts to find a hyperplane to maximize the distance between classified samples.

Input Columns #

Param name	Type	Default	Description
featuresCol	Vector	`"features"`	Feature vector.
labelCol	Integer	`"label"`	Label to predict.
weightCol	Double	`"weight"`	Weight of sample.

Output Columns #

Param name	Type	Default	Description
predictionCol	Integer	`"prediction"`	Label of the max probability.
rawPredictionCol	Vector	`"rawPrediction"`	Vector of the probability of each label.

Parameters #

Below are the parameters required by LinearSVCModel.

Key	Default	Type	Required	Description
featuresCol	`"features"`	String	no	Features column name.
predictionCol	`"prediction"`	String	no	Prediction column name.
rawPredictionCol	`"rawPrediction"`	String	no	Raw prediction column name.
threshold	`0.0`	Double	no	Threshold in binary classification prediction applied to rawPrediction.

LinearSVC needs parameters above and also below.

Key	Default	Type	Required	Description
labelCol	`"label"`	String	no	Label column name.
weightCol	`null`	String	no	Weight column name.
maxIter	`20`	Integer	no	Maximum number of iterations.
reg	`0.`	Double	no	Regularization parameter.
elasticNet	`0.`	Double	no	ElasticNet parameter.
learningRate	`0.1`	Double	no	Learning rate of optimization method.
globalBatchSize	`32`	Integer	no	Global batch size of training algorithms.
tol	`1e-6`	Double	no	Convergence tolerance for iterative algorithms.

Examples #

Java

import org.apache.flink.ml.classification.linearsvc.LinearSVC;
import org.apache.flink.ml.classification.linearsvc.LinearSVCModel;
import org.apache.flink.ml.linalg.DenseVector;
import org.apache.flink.ml.linalg.Vectors;
import org.apache.flink.streaming.api.datastream.DataStream;
import org.apache.flink.streaming.api.environment.StreamExecutionEnvironment;
import org.apache.flink.table.api.Table;
import org.apache.flink.table.api.bridge.java.StreamTableEnvironment;
import org.apache.flink.types.Row;
import org.apache.flink.util.CloseableIterator;

/** Simple program that trains a LinearSVC model and uses it for classification. */
public class LinearSVCExample {
    public static void main(String[] args) {
        StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
        StreamTableEnvironment tEnv = StreamTableEnvironment.create(env);

        // Generates input data.
        DataStream<Row> inputStream =
                env.fromElements(
                        Row.of(Vectors.dense(1, 2, 3, 4), 0., 1.),
                        Row.of(Vectors.dense(2, 2, 3, 4), 0., 2.),
                        Row.of(Vectors.dense(3, 2, 3, 4), 0., 3.),
                        Row.of(Vectors.dense(4, 2, 3, 4), 0., 4.),
                        Row.of(Vectors.dense(5, 2, 3, 4), 0., 5.),
                        Row.of(Vectors.dense(11, 2, 3, 4), 1., 1.),
                        Row.of(Vectors.dense(12, 2, 3, 4), 1., 2.),
                        Row.of(Vectors.dense(13, 2, 3, 4), 1., 3.),
                        Row.of(Vectors.dense(14, 2, 3, 4), 1., 4.),
                        Row.of(Vectors.dense(15, 2, 3, 4), 1., 5.));
        Table inputTable = tEnv.fromDataStream(inputStream).as("features", "label", "weight");

        // Creates a LinearSVC object and initializes its parameters.
        LinearSVC linearSVC = new LinearSVC().setWeightCol("weight");

        // Trains the LinearSVC Model.
        LinearSVCModel linearSVCModel = linearSVC.fit(inputTable);

        // Uses the LinearSVC Model for predictions.
        Table outputTable = linearSVCModel.transform(inputTable)[0];

        // Extracts and displays the results.
        for (CloseableIterator<Row> it = outputTable.execute().collect(); it.hasNext(); ) {
            Row row = it.next();
            DenseVector features = (DenseVector) row.getField(linearSVC.getFeaturesCol());
            double expectedResult = (Double) row.getField(linearSVC.getLabelCol());
            double predictionResult = (Double) row.getField(linearSVC.getPredictionCol());
            DenseVector rawPredictionResult =
                    (DenseVector) row.getField(linearSVC.getRawPredictionCol());
            System.out.printf(
                    "Features: %-25s \tExpected Result: %s \tPrediction Result: %s \tRaw Prediction Result: %s\n",
                    features, expectedResult, predictionResult, rawPredictionResult);
        }
    }
}

Python

# Simple program that trains a LinearSVC model and uses it for classification.

from pyflink.common import Types
from pyflink.datastream import StreamExecutionEnvironment
from pyflink.ml.linalg import Vectors, DenseVectorTypeInfo
from pyflink.ml.classification.linearsvc import LinearSVC
from pyflink.table import StreamTableEnvironment

# create a new StreamExecutionEnvironment
env = StreamExecutionEnvironment.get_execution_environment()

# create a StreamTableEnvironment
t_env = StreamTableEnvironment.create(env)

# generate input data
input_table = t_env.from_data_stream(
    env.from_collection([
        (Vectors.dense([1, 2, 3, 4]), 0., 1.),
        (Vectors.dense([2, 2, 3, 4]), 0., 2.),
        (Vectors.dense([3, 2, 3, 4]), 0., 3.),
        (Vectors.dense([4, 2, 3, 4]), 0., 4.),
        (Vectors.dense([5, 2, 3, 4]), 0., 5.),
        (Vectors.dense([11, 2, 3, 4]), 1., 1.),
        (Vectors.dense([12, 2, 3, 4]), 1., 2.),
        (Vectors.dense([13, 2, 3, 4]), 1., 3.),
        (Vectors.dense([14, 2, 3, 4]), 1., 4.),
        (Vectors.dense([15, 2, 3, 4]), 1., 5.),
    ],
        type_info=Types.ROW_NAMED(
            ['features', 'label', 'weight'],
            [DenseVectorTypeInfo(), Types.DOUBLE(), Types.DOUBLE()])
    ))

# create a linear svc object and initialize its parameters
linear_svc = LinearSVC().set_weight_col('weight')

# train the linear svc model
model = linear_svc.fit(input_table)

# use the linear svc model for predictions
output = model.transform(input_table)[0]

# extract and display the results
field_names = output.get_schema().get_field_names()
for result in t_env.to_data_stream(output).execute_and_collect():
    features = result[field_names.index(linear_svc.get_features_col())]
    expected_result = result[field_names.index(linear_svc.get_label_col())]
    prediction_result = result[field_names.index(linear_svc.get_prediction_col())]
    raw_prediction_result = result[field_names.index(linear_svc.get_raw_prediction_col())]
    print('Features: ' + str(features) + ' \tExpected Result: ' + str(expected_result)
          + ' \tPrediction Result: ' + str(prediction_result)
          + ' \tRaw Prediction Result: ' + str(raw_prediction_result))