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tmp/generi
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5efd5e8304 | |||
d2c8423b6f | |||
2a2c5e8765 | |||
47a9bf0e9a | |||
b8bf56bc42 | |||
597c27e615 | |||
40ffa8d6fc | |||
1c5113da29 | |||
4f2ebb17ff | |||
8fa42450b2 | |||
e0125f0b26 |
@ -0,0 +1,45 @@
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/*
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* Copyright 2018-2024 KMath contributors.
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* Use of this source code is governed by the Apache 2.0 license that can be found in the license/LICENSE.txt file.
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*/
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package space.kscience.kmath.series
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import space.kscience.kmath.operations.algebra
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import space.kscience.kmath.operations.bufferAlgebra
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import space.kscience.kmath.structures.*
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import space.kscience.kmath.operations.invoke
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import space.kscience.plotly.*
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import space.kscience.plotly.models.Scatter
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import kotlin.math.sin
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private val customAlgebra = (Double.algebra.bufferAlgebra) { SeriesAlgebra(this) { it.toDouble() } }
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fun main(): Unit = (customAlgebra) {
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val signal = DoubleArray(800) {
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sin(it.toDouble() / 10.0) + 3.5 * sin(it.toDouble() / 60.0)
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}.asBuffer().moveTo(0)
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val emd = empiricalModeDecomposition(
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sConditionThreshold = 1,
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maxSiftIterations = 15,
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siftingDelta = 1e-2,
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nModes = 4
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).decompose(signal)
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println("EMD: ${emd.modes.size} modes extracted, terminated because ${emd.terminatedBecause}")
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fun Plot.series(name: String, buffer: Buffer<Double>, block: Scatter.() -> Unit = {}) {
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this.scatter {
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this.name = name
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this.x.numbers = buffer.labels
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this.y.doubles = buffer.toDoubleArray()
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block()
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}
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}
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Plotly.plot {
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series("Signal", signal)
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emd.modes.forEachIndexed { index, it ->
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series("Mode ${index+1}", it)
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}
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}.makeFile(resourceLocation = ResourceLocation.REMOTE)
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}
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@ -14,6 +14,7 @@ kotlin.sourceSets {
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dependencies {
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dependencies {
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api(projects.kmathCoroutines)
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api(projects.kmathCoroutines)
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//implementation(spclibs.atomicfu)
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//implementation(spclibs.atomicfu)
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api(project(":kmath-functions"))
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}
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}
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}
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}
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@ -0,0 +1,288 @@
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/*
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* Copyright 2018-2024 KMath contributors.
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* Use of this source code is governed by the Apache 2.0 license that can be found in the license/LICENSE.txt file.
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*/
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package space.kscience.kmath.series
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import space.kscience.kmath.interpolation.SplineInterpolator
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import space.kscience.kmath.interpolation.interpolate
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import space.kscience.kmath.operations.*
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import space.kscience.kmath.structures.Buffer
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import space.kscience.kmath.structures.last
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/**
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* Empirical mode decomposition of a signal represented as a [Series].
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*
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* @param seriesAlgebra context to perform operations in.
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* @param maxSiftIterations number of iterations in the mode extraction (sifting) process after which
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* the result is returned even if no other conditions are met.
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* @param sConditionThreshold one of the possible criteria for sifting process termination:
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* how many times in a row should a proto-mode satisfy the s-condition (the number of zeros differs from
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* the number of extrema no more than by 1) to be considered an empirical mode.
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* @param siftingDelta one of the possible criteria for sifting process termination: if relative difference of
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* two proto-modes obtained in a sequence is less that this number, the last proto-mode is considered
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* an empirical mode and returned.
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* @param nModes how many modes should be extracted at most. The algorithm may return fewer modes if it was not
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* possible to extract more modes from the signal.
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*/
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public class EmpiricalModeDecomposition<T: Comparable<T>, A: Field<T>, BA, L: T> (
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private val seriesAlgebra: SeriesAlgebra<T, A, BA, L>,
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private val sConditionThreshold: Int = 15,
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private val maxSiftIterations: Int = 20,
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private val siftingDelta: T,
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private val nModes: Int = 6
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) where BA: BufferAlgebra<T, A>, BA: FieldOps<Buffer<T>> {
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/**
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* Take a signal, construct an upper and a lower envelopes, find the mean value of two,
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* represented as a series.
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* @param signal Signal to compute on
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*
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* @return mean [Series] or `null`. `null` is returned in case
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* the signal does not have enough extrema to construct envelopes.
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*/
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private fun findMean(signal: Series<T>): Series<T>? = (seriesAlgebra) {
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val interpolator = SplineInterpolator(elementAlgebra)
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val makeBuffer = elementAlgebra.bufferFactory
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fun generateEnvelope(extrema: List<Int>, paddedExtremeValues: Buffer<T>): Series<T> {
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val envelopeFunction = interpolator.interpolate(
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makeBuffer(extrema.size) { signal.labels[extrema[it]] },
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paddedExtremeValues
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)
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return signal.mapWithLabel { _, label ->
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// For some reason PolynomialInterpolator is exclusive and the right boundary
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// TODO Notify interpolator authors
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envelopeFunction(label) ?: paddedExtremeValues.last()
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// need to make the interpolator yield values outside boundaries?
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}
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}
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// Extrema padding (experimental) TODO padding needs a dedicated function
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val maxima = listOf(0) + signal.peaks() + (signal.size - 1)
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val maxValues = makeBuffer(maxima.size) { signal[maxima[it]] }
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if (maxValues[0] < maxValues[1]) {
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maxValues[0] = maxValues[1]
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}
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if (maxValues.last() < maxValues[maxValues.size - 2]) {
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maxValues[maxValues.size - 1] = maxValues[maxValues.size - 2]
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}
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val minima = listOf(0) + signal.troughs() + (signal.size - 1)
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val minValues = makeBuffer(minima.size) { signal[minima[it]] }
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if (minValues[0] > minValues[1]) {
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minValues[0] = minValues[1]
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}
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if (minValues.last() > minValues[minValues.size - 2]) {
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minValues[minValues.size - 1] = minValues[minValues.size - 2]
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}
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return if (maxima.size < 3 || minima.size < 3) null else { // maybe make an early return?
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val upperEnvelope = generateEnvelope(maxima, maxValues)
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val lowerEnvelope = generateEnvelope(minima, minValues)
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return (upperEnvelope + lowerEnvelope).map { it * 0.5 }
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}
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}
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/**
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* Extract a single empirical mode from a signal. This process is called sifting, hence the name.
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* @param signal Signal to extract a mode from. The first mode is extracted from the initial signal,
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* subsequent modes are extracted from the residuals between the signal and all previous modes.
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*
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* @return [SiftingResult.NotEnoughExtrema] is returned if the signal has too few extrema to extract a mode.
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* Success of an appropriate type (See [SiftingResult.Success] class) is returned otherwise.
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*/
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private fun sift(signal: Series<T>): SiftingResult = siftInner(signal, 1, 0)
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/**
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* Compute a single iteration of the sifting process.
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*/
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private tailrec fun siftInner(
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prevMode: Series<T>,
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iterationNumber: Int,
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sNumber: Int
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): SiftingResult = (seriesAlgebra) {
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val mean = findMean(prevMode) ?:
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return if (iterationNumber == 1) SiftingResult.NotEnoughExtrema
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else SiftingResult.SignalFlattened(prevMode)
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val mode = prevMode.zip(mean) { p, m -> p - m }
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val newSNumber = if (sCondition(mode)) sNumber + 1 else sNumber
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return when {
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iterationNumber >= maxSiftIterations -> SiftingResult.MaxIterationsReached(mode)
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sNumber >= sConditionThreshold -> SiftingResult.SNumberReached(mode)
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relativeDifference(mode, prevMode) < (elementAlgebra) { siftingDelta * mode.size } ->
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SiftingResult.DeltaReached(mode)
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else -> siftInner(mode, iterationNumber + 1, newSNumber)
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}
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}
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/**
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* Extract [nModes] empirical modes from a signal represented by a time series.
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* @param signal Signal to decompose.
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* @return [EMDecompositionResult] with an appropriate reason for algorithm termination
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* (see [EMDTerminationReason] for possible reasons).
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* Modes returned in a list which contains as many modes as it was possible
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* to extract before triggering one of the termination conditions.
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*/
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public fun decompose(signal: Series<T>): EMDecompositionResult<T> = (seriesAlgebra) {
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val modes = mutableListOf<Series<T>>()
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var residual = signal
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repeat(nModes) {
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val nextMode = when(val r = sift(residual)) {
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SiftingResult.NotEnoughExtrema ->
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return EMDecompositionResult(
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if (it == 0) EMDTerminationReason.SIGNAL_TOO_FLAT
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else EMDTerminationReason.ALL_POSSIBLE_MODES_EXTRACTED,
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modes,
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residual
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)
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is SiftingResult.Success<*> -> r.result
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}
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modes.add(nextMode as Series<T>) // TODO remove unchecked cast
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residual = residual.zip(nextMode) { l, r -> l - r }
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}
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return EMDecompositionResult(EMDTerminationReason.MAX_MODES_REACHED, modes, residual)
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}
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}
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/**
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* Shortcut to retrieve a decomposition factory from a [SeriesAlgebra] scope.
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* @receiver scope to perform operations in.
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* @param maxSiftIterations number of iterations in the mode extraction (sifting) process after which
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* the result is returned even if no other conditions are met.
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* @param sConditionThreshold one of the possible criteria for sifting process termination:
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* how many times in a row should a proto-mode satisfy the s-condition (the number of zeros differs from
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* the number of extrema no more than by 1) to be considered an empirical mode.
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* @param siftingDelta one of the possible criteria for sifting process termination: if relative difference of
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* two proto-modes obtained in a sequence is less that this number, the last proto-mode is considered
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* an empirical mode and returned.
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* @param nModes how many modes should be extracted at most. The algorithm may return fewer modes if it was not
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* possible to extract more modes from the signal.
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*/
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public fun <T: Comparable<T>, L: T, A: Field<T>, BA> SeriesAlgebra<T, A, BA, L>.empiricalModeDecomposition(
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sConditionThreshold: Int = 15,
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maxSiftIterations: Int = 20,
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siftingDelta: T,
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nModes: Int = 3
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): EmpiricalModeDecomposition<T, A, BA, L>
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where BA: BufferAlgebra<T, A>, BA: FieldOps<Buffer<T>> = EmpiricalModeDecomposition(
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seriesAlgebra = this,
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sConditionThreshold = sConditionThreshold,
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maxSiftIterations = maxSiftIterations,
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siftingDelta = siftingDelta,
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nModes = nModes
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)
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/**
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* Brute force count all zeros in the series.
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*/
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private fun <T: Comparable<T>, A: Ring<T>, BA> SeriesAlgebra<T, A, BA, *>.countZeros(
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signal: Series<T>
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): Int where BA: BufferAlgebra<T, A>, BA: FieldOps<Buffer<T>> {
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require(signal.size >= 2) { "Expected series with at least 2 elements, but got ${signal.size} elements" }
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data class SignCounter(val prevSign: Int, val zeroCount: Int)
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fun strictSign(arg: T): Int = if (arg > elementAlgebra.zero) 1 else -1
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return signal.fold(SignCounter(strictSign(signal[0]), 0)) { acc, it ->
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val currentSign = strictSign(it)
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if (acc.prevSign != currentSign) SignCounter(currentSign, acc.zeroCount + 1)
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else SignCounter(currentSign, acc.zeroCount)
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}.zeroCount
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}
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/**
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* Compute relative difference of two series.
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*/
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private fun <T, A: Ring<T>, BA> SeriesAlgebra<T, A, BA, *>.relativeDifference(
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current: Series<T>,
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previous: Series<T>
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): T where BA: BufferAlgebra<T, A>, BA: FieldOps<Buffer<T>> = (bufferAlgebra) {
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((current - previous) * (current - previous))
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.div(previous * previous)
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.fold(elementAlgebra.zero) { acc, it -> acc + it}
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}
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/**
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* Brute force count all extrema of a series.
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*/
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private fun <T: Comparable<T>> Series<T>.countExtrema(): Int {
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require(size >= 3) { "Expected series with at least 3 elements, but got $size elements" }
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return peaks().size + troughs().size
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}
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|
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|
/**
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|
* Check whether the numbers of zeroes and extrema of a series differ by no more than 1.
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* This is a necessary condition of an empirical mode.
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|
*/
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private fun <T: Comparable<T>, A: Ring<T>, BA> SeriesAlgebra<T, A, BA, *>.sCondition(
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|
signal: Series<T>
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|
): Boolean where BA: BufferAlgebra<T, A>, BA: FieldOps<Buffer<T>> =
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|
(signal.countExtrema() - countZeros(signal)) in -1..1
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|
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|
internal sealed interface SiftingResult {
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|
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|
/**
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|
* Represents a condition when a mode has been successfully
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|
* extracted in a sifting process.
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|
*/
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|
open class Success<T>(val result: Series<T>): SiftingResult
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|
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|
/**
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|
* Returned when no termination condition was reached and the proto-mode
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|
* has become too flat (with not enough extrema to build envelopes)
|
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|
* after several sifting iterations.
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|
*/
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|
class SignalFlattened<T>(result: Series<T>) : Success<T>(result)
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|
|
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|
/**
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|
* Returned when sifting process has been terminated due to the
|
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|
* S-number condition being reached.
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|
*/
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|
class SNumberReached<T>(result: Series<T>) : Success<T>(result)
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|
|
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|
/**
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|
* Returned when sifting process has been terminated due to the
|
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|
* delta condition (Cauchy criterion) being reached.
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|
*/
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|
class DeltaReached<T>(result: Series<T>) : Success<T>(result)
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|
|
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|
/**
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|
* Returned when sifting process has been terminated after
|
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|
* executing the maximum number of iterations (specified when creating an instance
|
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|
* of [EmpiricalModeDecomposition]).
|
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|
*/
|
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|
class MaxIterationsReached<T>(result: Series<T>): Success<T>(result)
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|
|
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|
/**
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|
* Returned when the submitted signal has not enough extrema to build envelopes,
|
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|
* i.e. when [SignalFlattened] condition has already been reached before the first sifting iteration.
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|
*/
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|
data object NotEnoughExtrema : SiftingResult
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|
|
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|
}
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|
|
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|
public enum class EMDTerminationReason {
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|
/**
|
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|
* Returned when the signal is too flat, i.e. there are too few extrema
|
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|
* to build envelopes necessary to extract modes.
|
||||||
|
*/
|
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|
SIGNAL_TOO_FLAT,
|
||||||
|
|
||||||
|
/**
|
||||||
|
* Returned when there has been extracted as many modes as
|
||||||
|
* specified when creating the instance of [EmpiricalModeDecomposition]
|
||||||
|
*/
|
||||||
|
MAX_MODES_REACHED,
|
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|
|
||||||
|
/**
|
||||||
|
* Returned when the algorithm terminated after finding impossible
|
||||||
|
* to extract more modes from the signal and the maximum number
|
||||||
|
* of modes (specified when creating an instance of [EmpiricalModeDecomposition])
|
||||||
|
* has not yet been reached.
|
||||||
|
*/
|
||||||
|
ALL_POSSIBLE_MODES_EXTRACTED
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||||||
|
}
|
||||||
|
|
||||||
|
public data class EMDecompositionResult<T>(
|
||||||
|
val terminatedBecause: EMDTerminationReason,
|
||||||
|
val modes: List<Series<T>>,
|
||||||
|
val residual: Series<T>
|
||||||
|
)
|
@ -169,7 +169,7 @@ public open class SeriesAlgebra<T, out A : Ring<T>, out BA : BufferAlgebra<T, A>
|
|||||||
public inline fun Buffer<T>.mapWithLabel(crossinline transform: A.(arg: T, label: L) -> T): Series<T> {
|
public inline fun Buffer<T>.mapWithLabel(crossinline transform: A.(arg: T, label: L) -> T): Series<T> {
|
||||||
val labels = labels
|
val labels = labels
|
||||||
val buf = elementAlgebra.bufferFactory(size) {
|
val buf = elementAlgebra.bufferFactory(size) {
|
||||||
elementAlgebra.transform(getByOffset(it), labels[it])
|
elementAlgebra.transform(get(it), labels[it])
|
||||||
}
|
}
|
||||||
return buf.moveTo(offsetIndices.first)
|
return buf.moveTo(offsetIndices.first)
|
||||||
}
|
}
|
||||||
|
@ -0,0 +1,89 @@
|
|||||||
|
/*
|
||||||
|
* Copyright 2018-2024 KMath contributors.
|
||||||
|
* Use of this source code is governed by the Apache 2.0 license that can be found in the license/LICENSE.txt file.
|
||||||
|
*/
|
||||||
|
|
||||||
|
package space.kscience.kmath.series
|
||||||
|
|
||||||
|
|
||||||
|
public enum class PlateauEdgePolicy {
|
||||||
|
/**
|
||||||
|
* Midpoints of plateau are returned, edges not belonging to a plateau are ignored.
|
||||||
|
*
|
||||||
|
* A midpoint is the index closest to the average of indices of the left and right edges
|
||||||
|
* of the plateau:
|
||||||
|
*
|
||||||
|
* `val midpoint = ((leftEdge + rightEdge) / 2).toInt`
|
||||||
|
*/
|
||||||
|
AVERAGE,
|
||||||
|
|
||||||
|
/**
|
||||||
|
* Both left and right edges are returned.
|
||||||
|
*/
|
||||||
|
KEEP_ALL_EDGES,
|
||||||
|
|
||||||
|
/**
|
||||||
|
* Only right edges are returned.
|
||||||
|
*/
|
||||||
|
KEEP_RIGHT_EDGES,
|
||||||
|
|
||||||
|
/**
|
||||||
|
* Only left edges are returned.
|
||||||
|
*/
|
||||||
|
KEEP_LEFT_EDGES,
|
||||||
|
|
||||||
|
/**
|
||||||
|
* Ignore plateau, only peaks (troughs) with values strictly greater (less)
|
||||||
|
* than values of the adjacent points are returned.
|
||||||
|
*/
|
||||||
|
IGNORE
|
||||||
|
}
|
||||||
|
|
||||||
|
|
||||||
|
public fun <T: Comparable<T>> Series<T>.peaks(
|
||||||
|
plateauEdgePolicy: PlateauEdgePolicy = PlateauEdgePolicy.AVERAGE
|
||||||
|
): List<Int> = findPeaks(plateauEdgePolicy, { other -> this > other }, { other -> this >= other })
|
||||||
|
|
||||||
|
public fun <T: Comparable<T>> Series<T>.troughs(
|
||||||
|
plateauEdgePolicy: PlateauEdgePolicy = PlateauEdgePolicy.AVERAGE
|
||||||
|
): List<Int> = findPeaks(plateauEdgePolicy, { other -> this < other }, { other -> this <= other })
|
||||||
|
|
||||||
|
|
||||||
|
private fun <T: Comparable<T>> Series<T>.findPeaks(
|
||||||
|
plateauPolicy: PlateauEdgePolicy = PlateauEdgePolicy.AVERAGE,
|
||||||
|
cmpStrong: T.(T) -> Boolean,
|
||||||
|
cmpWeak: T.(T) -> Boolean
|
||||||
|
): List<Int> {
|
||||||
|
require(size >= 3) { "Expected series with at least 3 elements, but got $size elements" }
|
||||||
|
if (plateauPolicy == PlateauEdgePolicy.AVERAGE) return peaksWithPlateau(cmpStrong)
|
||||||
|
fun peakCriterion(left: T, middle: T, right: T): Boolean = when(plateauPolicy) {
|
||||||
|
PlateauEdgePolicy.KEEP_LEFT_EDGES -> middle.cmpStrong(left) && middle.cmpWeak(right)
|
||||||
|
PlateauEdgePolicy.KEEP_RIGHT_EDGES -> middle.cmpWeak(left) && middle.cmpStrong(right)
|
||||||
|
PlateauEdgePolicy.KEEP_ALL_EDGES ->
|
||||||
|
(middle.cmpStrong(left) && middle.cmpWeak(right)) || (middle.cmpWeak(left) && middle.cmpStrong(right))
|
||||||
|
else -> middle.cmpStrong(right) && middle.cmpStrong(left)
|
||||||
|
}
|
||||||
|
val indices = mutableListOf<Int>()
|
||||||
|
for (index in 1 .. size - 2) {
|
||||||
|
val left = this[index - 1]
|
||||||
|
val middle = this[index]
|
||||||
|
val right = this[index + 1]
|
||||||
|
if (peakCriterion(left, middle, right)) indices.add(index)
|
||||||
|
}
|
||||||
|
return indices
|
||||||
|
}
|
||||||
|
|
||||||
|
|
||||||
|
private fun <T: Comparable<T>> Series<T>.peaksWithPlateau(cmpStrong: T.(T) -> Boolean): List<Int> {
|
||||||
|
val peaks = mutableListOf<Int>()
|
||||||
|
tailrec fun peaksPlateauInner(index: Int) {
|
||||||
|
val nextUnequal = (index + 1 ..< size).firstOrNull { this[it] != this[index] } ?: (size - 1)
|
||||||
|
val newIndex = if (this[index].cmpStrong(this[index - 1]) && this[index].cmpStrong(this[nextUnequal])) {
|
||||||
|
peaks.add((index + nextUnequal) / 2)
|
||||||
|
nextUnequal
|
||||||
|
} else index + 1
|
||||||
|
if (newIndex < size - 1) peaksPlateauInner(newIndex)
|
||||||
|
}
|
||||||
|
peaksPlateauInner(1)
|
||||||
|
return peaks
|
||||||
|
}
|
Loading…
Reference in New Issue
Block a user