KSWIN¶
Kolmogorov-Smirnov Windowing method for concept drift detection.
Parameters¶
-
alpha
Type → float
Default →
0.005
Probability for the test statistic of the Kolmogorov-Smirnov-Test. The alpha parameter is very sensitive, therefore should be set below 0.01.
-
window_size
Type → int
Default →
100
Size of the sliding window.
-
stat_size
Type → int
Default →
30
Size of the statistic window.
-
seed
Type → int | None
Default →
None
Random seed for reproducibility.
-
window
Type → typing.Iterable | None
Default →
None
Already collected data to avoid cold start.
Attributes¶
-
drift_detected
Whether or not a drift is detected following the last update.
Examples¶
import random
from river import drift
rng = random.Random(12345)
kswin = drift.KSWIN(alpha=0.0001, seed=42)
data_stream = rng.choices([0, 1], k=1000) + rng.choices(range(4, 8), k=1000)
for i, val in enumerate(data_stream):
_ = kswin.update(val)
if kswin.drift_detected:
print(f"Change detected at index {i}, input value: {val}")
Change detected at index 1016, input value: 6
Methods¶
update
Update the change detector with a single data point.
Adds an element on top of the sliding window and removes the oldest one from the window. Afterwards, the KS-test is performed.
Parameters
- x — 'int | float'
Returns
DriftDetector: self
Notes¶
KSWIN (Kolmogorov-Smirnov Windowing) is a concept change detection method based on the Kolmogorov-Smirnov (KS) statistical test. KS-test is a statistical test with no assumption of underlying data distribution. KSWIN can monitor data or performance distributions. Note that the detector accepts one dimensional input as array.
KSWIN maintains a sliding window \(\Psi\) of fixed size \(n\) (window_size). The last \(r\) (stat_size) samples of \(\Psi\) are assumed to represent the last concept considered as \(R\). From the first \(n-r\) samples of \(\Psi\), \(r\) samples are uniformly drawn, representing an approximated last concept \(W\).
The KS-test is performed on the windows \(R\) and \(W\) of the same size. KS -test compares the distance of the empirical cumulative data distribution \(dist(R,W)\).
A concept drift is detected by KSWIN if:
The difference in empirical data distributions between the windows \(R\) and \(W\) is too large since \(R\) and \(W\) come from the same distribution.
-
Christoph Raab, Moritz Heusinger, Frank-Michael Schleif, Reactive Soft Prototype Computing for Concept Drift Streams, Neurocomputing, 2020, ↩