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Hyperplane

Hyperplane stream generator.

Generates a problem of prediction class of a rotation hyperplane. It was used as testbed for CVFDT and VFDT in 1.

A hyperplane in d-dimensional space is the set of points \(x\) that satisfy

\[\sum^{d}_{i=1} w_i x_i = w_0 = \sum^{d}_{i=1} w_i\]

where \(x_i\) is the i-th coordinate of \(x\).

  • Examples for which \(\sum^{d}_{i=1} w_i x_i > w_0\), are labeled positive.

  • Examples for which \(\sum^{d}_{i=1} w_i x_i \leq w_0\), are labeled negative.

Hyperplanes are useful for simulating time-changing concepts because we can change the orientation and position of the hyperplane in a smooth manner by changing the relative size of the weights. We introduce change to this dataset by adding drift to each weighted feature \(w_i = w_i + d \sigma\), where \(\sigma\) is the probability that the direction of change is reversed and \(d\) is the change applied to each example.

Parameters

  • seed

    Typeint | None

    DefaultNone

    Random seed for reproducibility.

  • n_features

    Typeint

    Default10

    The number of attributes to generate. Higher than 2.

  • n_drift_features

    Typeint

    Default2

    The number of attributes with drift. Higher than 2.

  • mag_change

    Typefloat

    Default0.0

    Magnitude of the change for every example. From 0.0 to 1.0.

  • noise_percentage

    Typefloat

    Default0.05

    Percentage of noise to add to the data. From 0.0 to 1.0.

  • sigma

    Typefloat

    Default0.1

    Probability that the direction of change is reversed. From 0.0 to 1.0.

Attributes

  • desc

    Return the description from the docstring.

Examples

from river.datasets import synth

dataset = synth.Hyperplane(seed=42, n_features=2)

for x, y in dataset.take(5):
    print(x, y)
{0: 0.2750, 1: 0.2232} 0
{0: 0.0869, 1: 0.4219} 1
{0: 0.0265, 1: 0.1988} 0
{0: 0.5892, 1: 0.8094} 0
{0: 0.3402, 1: 0.1554} 0

Methods

take

Iterate over the k samples.

Parameters

  • k'int'

Notes

The sample generation works as follows: The features are generated with the random number generator, initialized with the seed passed by the user. Then the classification function decides, as a function of the sum of the weighted features and the sum of the weights, whether the instance belongs to class 0 or class 1. The last step is to add noise and generate drift.


  1. G. Hulten, L. Spencer, and P. Domingos. Mining time-changing data streams. In KDD'01, pages 97-106, San Francisco, CA, 2001. ACM Press.