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updateDetector

Update settings of trained detector and recompute detection threshold

Since R2023a

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    Syntax

    updateDetector(d,data,Name=Value)

    Description

    updateDetector(d,data,Name=Value) updates the threshold and window settings of the detector d, then recomputes the detection threshold. For any name-value argument not specified, the function uses the current value of the corresponding parameter in the detector.

    Note

    When ThresholdMethod is set to "manual", you do not need to specify input signal data set data.

    example

    Examples

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    This example uses:

    Open Live Script

    Load a convolutional anomaly detector trained with three-channel sinusoidal signals. Display the model, threshold, and window properties of the detector.

    load sineWaveAnomalyDetector
D
    D = 
  deepSignalAnomalyDetectorCNN with properties:

                IsTrained: 1
              NumChannels: 3

   Model Information
                ModelType: 'convautoencoder'
               FilterSize: 8
               NumFilters: 32
      NumDownsampleLayers: 2
         DownsampleFactor: 2
       DropoutProbability: 0.2000

   Threshold Information
                Threshold: 0.0510
          ThresholdMethod: 'contaminationFraction'
       ThresholdParameter: 0.0100

   Window Information
             WindowLength: 1
            OverlapLength: 'auto'
    WindowLossAggregation: 'mean'

    Load the file sineWaveAnomalyData.mat, which contains two sets of synthetic three-channel sinusoidal signals.

    • sineWaveNormal contains the 10 sinusoids used to train the convolutional anomaly detector. Each signal has a series of small-amplitude impact-like imperfections but otherwise has stable amplitude and frequency.

    • sineWaveAbnormal contains three signals of similar length and amplitude to the training data. One of the signals has an abrupt, finite-time change in frequency. Another signal has a finite-duration amplitude change in one of its channels. A third has random spikes in each channel.

    Plot three normal signals and the three signals with anomalies.

    load sineWaveAnomalyData
 
tiledlayout(3,2,TileSpacing="compact",Padding="compact")
rnd = randperm(length(sineWaveNormal));
for kj = 1:length(sineWaveAbnormal)
    nexttile
    plot(sineWaveNormal{rnd(kj)})
    title("Normal Signal")
    nexttile
    plot(sineWaveAbnormal{kj})
    title("Signal with Anomalies")
end

    Figure contains 6 axes objects. Axes object 1 with title Normal Signal contains 3 objects of type line. Axes object 2 with title Signal with Anomalies contains 3 objects of type line. Axes object 3 with title Normal Signal contains 3 objects of type line. Axes object 4 with title Signal with Anomalies contains 3 objects of type line. Axes object 5 with title Normal Signal contains 3 objects of type line. Axes object 6 with title Signal with Anomalies contains 3 objects of type line.

    Update the anomaly detector using the training data.

    • Specify the regions to be labeled as anomalies as non-overlapping 50-sample windows.

    • Specify that the function compute the detection threshold as the mean window loss measured over the entire training data set and multiplied by 20.

    updateDetector(D,sineWaveNormal, ...
    WindowLength=50,OverlapLength=0, ...
    ThresholdMethod="mean",ThresholdParameter=20)

    Plot the second test signal and annotate the anomalies found by the updated detector.

    plotAnomalies(D,sineWaveAbnormal{2})

    Figure contains 3 axes objects. Axes object 1 with ylabel Channel 1 contains 3 objects of type line. One or more of the lines displays its values using only markers Axes object 2 with ylabel Channel 2 contains 3 objects of type line. One or more of the lines displays its values using only markers Axes object 3 with xlabel Samples, ylabel Channel 3 contains 3 objects of type line. One or more of the lines displays its values using only markers These objects represent Raw Signal, Anomalies.

    Input Arguments

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    Anomaly detector, specified as a deepSignalAnomalyDetectorCNN object, a deepSignalAnomalyDetectorLSTM object, or a deepSignalAnomalyDetectorLSTMForecaster object. Use the deepSignalAnomalyDetector function to create d.

    Signal data set, specified as one of these:

    • Nc-column matrix — A single multichannel signal observation (M = 1), where Nc is equal to the value of the NumChannels property of the detector.

    • M-element cell array — M multichannel signal observations, where each cell contains an Nc-column matrix.

    • Timetable — A single multichannel signal observation, contained in a MATLAB® timetable. The timetable must contain increasing, uniformly-sampled, and finite values. The timetable can have:

      • A single variable containing an Nc-column matrix, where each column corresponds to a signal channel.

      • Nc variables, where each variable contains a vector that corresponds to a signal channel.

    • Datastore — A signalDatastore, audioDatastore (Audio Toolbox), or arrayDatastore object. The detector uses the readall function to read all the signal observations contained in the datastore at once. You can also use a CombinedDatastore or TransformedDatastore object containing any of the supported datastores.

    Name-Value Arguments

    Specify optional pairs of arguments as Name1=Value1,...,NameN=ValueN, where Name is the argument name and Value is the corresponding value. Name-value arguments must appear after other arguments, but the order of the pairs does not matter.

    Example: MiniBatchSize=64,ExecutionEnvironment="cpu" instructs the function to use a mini-batch size of 64 and use the computer CPU to detect anomalies.

    Window length of each signal segment, specified as a positive integer or as "fullSignal".

    • If you specify WindowLength as an integer, the detector divides each input signal into segments. The length of each segment is equal to the specified value in samples.

    • If you specify WindowLength as "fullSignal", the detector treats each input signal as a single segment.

    Data Types: single | double | int8 | int16 | int32 | int64 | uint8 | uint16 | uint32 | uint64 | char | string

    Number of overlapped samples between window segments, specified as a positive integer or as "auto".

    • If you specify WindowLength and OverlapLength as integers, the detector sets the number of overlapped samples to the specified value. The number of overlapped samples must be less than the window length.

    • If you specify WindowLength as an integer and OverlapLength as "auto", the detector sets the number of overlapped samples to WindowLength – 1.

    • If you specify WindowLength as "fullSignal", you cannot specify OverlapLength as an integer.

    Data Types: single | double | int8 | int16 | int32 | int64 | uint8 | uint16 | uint32 | uint64 | logical | char | string

    Method to aggregate sample loss within each window segment, specified as one of these:

    • "max" — Compute the aggregated window loss as the maximum value of all the sample losses within the window.

    • "mean" — Compute the aggregated window loss as the mean value of all the sample losses within the window.

    • "median" — Compute the aggregated window loss as the median value of all the sample losses within the window.

    • "min" — Compute the aggregated window loss as the minimum value of all the sample losses within the window.

    The detector computes the detection loss of each sample within a window segment and aggregates the loss values over each window.

    Method to compute the detection threshold, specified as one of these:

    • "contaminationFraction" — Value corresponding to the detection of anomalies within a specified fraction of windows. The fraction value is specified by ThresholdParameter.

    • "max" — Maximum window loss measured over the entire training data set and multiplied by ThresholdParameter.

    • "median" — Median window loss measured over the entire training data set and multiplied by ThresholdParameter.

    • "mean" — Mean window loss measured over the entire training data set and multiplied by ThresholdParameter.

    • "manual" — Manual detection threshold value based on Threshold.

    • "customFunction" — Custom detection threshold value based on ThresholdFunction.

    If you specify ThresholdMethod, you can also specify ThresholdParameter, Threshold, or ThresholdFunction. The available threshold parameter depends on the specified detection method.

    Detection threshold, specified as a real scalar.

    • If ThresholdMethod is specified as "max", "mean", or "median", specify ThresholdParameter as a positive scalar. If you do not specify ThresholdParameter, the detector sets the threshold to 1.

    • If ThresholdMethod is specified as "contaminationFraction", specify ThresholdParameter as a nonnegative scalar less than 0.5. If you do not specify ThresholdParameter, the detector sets the threshold to 0.01.

    • If ThresholdMethod is specified as "customFunction" or "manual", this argument does not apply.

    Manual detection threshold, specified as a positive scalar. This argument applies only when ThresholdMethod is specified as "manual".

    Use this option when you do not want the detector to compute a threshold based on training data.

    Data Types: single | double | int8 | int16 | int32 | int64 | uint8 | uint16 | uint32 | uint64

    Function to compute custom detection threshold, specified as a function handle. This argument applies only when ThresholdMethod is specified as "customFunction".

    • The function must have two inputs:

      • The first input is a cell array of aggregated window loss values.

      • The second input is a cell array of sample loss values before aggregation.

      Each cell contains a loss vector for one signal observation.

    • The function must return a positive scalar corresponding to the detection threshold.

    Use this option when you want to compute a threshold based on training data.

    Data Types: function_handle

    Mini-batch size used by the network to compute reconstructed signals, specified as a positive integer scalar.

    Data Types: single | double | int8 | int16 | int32 | int64 | uint8 | uint16 | uint32 | uint64

    Execution environment used by the network, specified as one of these:

    • "auto" — If available, use the GPU. If the GPU is not available, use the CPU.

    • "gpu" — Use the GPU.

    • "cpu" — Use the CPU.

    Data Types: char | string

    Version History

    Introduced in R2023a

    See Also

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