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Example 56 with Max

use of org.apache.commons.math3.stat.descriptive.rank.Max in project GDSC-SMLM by aherbert.

the class DiffusionRateTest method plotJumpDistances.

/**
	 * Plot a cumulative histogram and standard histogram of the jump distances.
	 *
	 * @param title
	 *            the title
	 * @param jumpDistances
	 *            the jump distances
	 * @param dimensions
	 *            the number of dimensions for the jumps
	 * @param steps
	 *            the steps
	 */
private void plotJumpDistances(String title, DoubleData jumpDistances, int dimensions) {
    // Cumulative histogram
    // --------------------
    double[] values = jumpDistances.values();
    String title2 = title + " Cumulative Jump Distance " + dimensions + "D";
    double[][] jdHistogram = JumpDistanceAnalysis.cumulativeHistogram(values);
    Plot2 jdPlot = new Plot2(title2, "Distance (um^2)", "Cumulative Probability", jdHistogram[0], jdHistogram[1]);
    PlotWindow pw2 = Utils.display(title2, jdPlot);
    if (Utils.isNewWindow())
        idList[idCount++] = pw2.getImagePlus().getID();
    // Plot the expected function
    // This is the Chi-squared distribution: The sum of the squares of k independent
    // standard normal random variables with k = dimensions. It is a special case of
    // the gamma distribution. If the normals have non-unit variance the distribution 
    // is scaled.
    // Chi       ~ Gamma(k/2, 2)      // using the scale parameterisation of the gamma
    // s^2 * Chi ~ Gamma(k/2, 2*s^2)
    // So if s^2 = 2D:
    // 2D * Chi  ~ Gamma(k/2, 4D)
    double estimatedD = simpleD * simpleSteps;
    double max = Maths.max(values);
    double[] x = Utils.newArray(1000, 0, max / 1000);
    double k = dimensions / 2.0;
    double mean = 4 * estimatedD;
    GammaDistribution dist = new GammaDistribution(k, mean);
    double[] y = new double[x.length];
    for (int i = 0; i < x.length; i++) y[i] = dist.cumulativeProbability(x[i]);
    jdPlot.setColor(Color.red);
    jdPlot.addPoints(x, y, Plot.LINE);
    Utils.display(title2, jdPlot);
    // Histogram
    // ---------
    title2 = title + " Jump " + dimensions + "D";
    int plotId = Utils.showHistogram(title2, jumpDistances, "Distance (um^2)", 0, 0, Math.max(20, values.length / 1000));
    if (Utils.isNewWindow())
        idList[idCount++] = plotId;
    // Recompute the expected function
    for (int i = 0; i < x.length; i++) y[i] = dist.density(x[i]);
    // Scale to have the same area
    if (Utils.xValues.length > 1) {
        final double area1 = jumpDistances.size() * (Utils.xValues[1] - Utils.xValues[0]);
        final double area2 = dist.cumulativeProbability(x[x.length - 1]);
        final double scaleFactor = area1 / area2;
        for (int i = 0; i < y.length; i++) y[i] *= scaleFactor;
    }
    jdPlot = Utils.plot;
    jdPlot.setColor(Color.red);
    jdPlot.addPoints(x, y, Plot.LINE);
    Utils.display(WindowManager.getImage(plotId).getTitle(), jdPlot);
}
Also used : PlotWindow(ij.gui.PlotWindow) Plot2(ij.gui.Plot2) GammaDistribution(org.apache.commons.math3.distribution.GammaDistribution)

Example 57 with Max

use of org.apache.commons.math3.stat.descriptive.rank.Max in project GDSC-SMLM by aherbert.

the class BenchmarkSpotFit method summariseResults.

private void summariseResults(TIntObjectHashMap<FilterCandidates> filterCandidates, long runTime, final PreprocessedPeakResult[] preprocessedPeakResults, int nUniqueIDs) {
    createTable();
    // Summarise the fitting results. N fits, N failures. 
    // Optimal match statistics if filtering is perfect (since fitting is not perfect).
    StoredDataStatistics distanceStats = new StoredDataStatistics();
    StoredDataStatistics depthStats = new StoredDataStatistics();
    // Get stats for all fitted results and those that match 
    // Signal, SNR, Width, xShift, yShift, Precision
    createFilterCriteria();
    StoredDataStatistics[][] stats = new StoredDataStatistics[3][filterCriteria.length];
    for (int i = 0; i < stats.length; i++) for (int j = 0; j < stats[i].length; j++) stats[i][j] = new StoredDataStatistics();
    final double nmPerPixel = simulationParameters.a;
    double tp = 0, fp = 0;
    int failcTP = 0, failcFP = 0;
    int cTP = 0, cFP = 0;
    int[] singleStatus = null, multiStatus = null, doubletStatus = null, multiDoubletStatus = null;
    singleStatus = new int[FitStatus.values().length];
    multiStatus = new int[singleStatus.length];
    doubletStatus = new int[singleStatus.length];
    multiDoubletStatus = new int[singleStatus.length];
    // Easier to materialise the values since we have a lot of non final variables to manipulate
    final int[] frames = new int[filterCandidates.size()];
    final FilterCandidates[] candidates = new FilterCandidates[filterCandidates.size()];
    final int[] counter = new int[1];
    filterCandidates.forEachEntry(new TIntObjectProcedure<FilterCandidates>() {

        public boolean execute(int a, FilterCandidates b) {
            frames[counter[0]] = a;
            candidates[counter[0]] = b;
            counter[0]++;
            return true;
        }
    });
    for (FilterCandidates result : candidates) {
        // Count the number of fit results that matched (tp) and did not match (fp)
        tp += result.tp;
        fp += result.fp;
        for (int i = 0; i < result.fitResult.length; i++) {
            if (result.spots[i].match)
                cTP++;
            else
                cFP++;
            final MultiPathFitResult fitResult = result.fitResult[i];
            if (singleStatus != null && result.spots[i].match) {
                // Debugging reasons for fit failure
                addStatus(singleStatus, fitResult.getSingleFitResult());
                addStatus(multiStatus, fitResult.getMultiFitResult());
                addStatus(doubletStatus, fitResult.getDoubletFitResult());
                addStatus(multiDoubletStatus, fitResult.getMultiDoubletFitResult());
            }
            if (noMatch(fitResult)) {
                if (result.spots[i].match)
                    failcTP++;
                else
                    failcFP++;
            }
            // We have multi-path results.
            // We want statistics for:
            // [0] all fitted spots
            // [1] fitted spots that match a result
            // [2] fitted spots that do not match a result
            addToStats(fitResult.getSingleFitResult(), stats);
            addToStats(fitResult.getMultiFitResult(), stats);
            addToStats(fitResult.getDoubletFitResult(), stats);
            addToStats(fitResult.getMultiDoubletFitResult(), stats);
        }
        // Statistics on spots that fit an actual result
        for (int i = 0; i < result.match.length; i++) {
            if (!result.match[i].isFitResult())
                // For now just ignore the candidates that matched
                continue;
            FitMatch fitMatch = (FitMatch) result.match[i];
            distanceStats.add(fitMatch.d * nmPerPixel);
            depthStats.add(fitMatch.z * nmPerPixel);
        }
    }
    // Store data for computing correlation
    double[] i1 = new double[depthStats.getN()];
    double[] i2 = new double[i1.length];
    double[] is = new double[i1.length];
    int ci = 0;
    for (FilterCandidates result : candidates) {
        for (int i = 0; i < result.match.length; i++) {
            if (!result.match[i].isFitResult())
                // For now just ignore the candidates that matched
                continue;
            FitMatch fitMatch = (FitMatch) result.match[i];
            ScoredSpot spot = result.spots[fitMatch.i];
            i1[ci] = fitMatch.predictedSignal;
            i2[ci] = fitMatch.actualSignal;
            is[ci] = spot.spot.intensity;
            ci++;
        }
    }
    // We want to compute the Jaccard against the spot metric
    // Filter the results using the multi-path filter
    ArrayList<MultiPathFitResults> multiPathResults = new ArrayList<MultiPathFitResults>(filterCandidates.size());
    for (int i = 0; i < frames.length; i++) {
        int frame = frames[i];
        MultiPathFitResult[] multiPathFitResults = candidates[i].fitResult;
        int totalCandidates = candidates[i].spots.length;
        int nActual = actualCoordinates.get(frame).size();
        multiPathResults.add(new MultiPathFitResults(frame, multiPathFitResults, totalCandidates, nActual));
    }
    // Score the results and count the number returned
    List<FractionalAssignment[]> assignments = new ArrayList<FractionalAssignment[]>();
    final TIntHashSet set = new TIntHashSet(nUniqueIDs);
    FractionScoreStore scoreStore = new FractionScoreStore() {

        public void add(int uniqueId) {
            set.add(uniqueId);
        }
    };
    MultiPathFitResults[] multiResults = multiPathResults.toArray(new MultiPathFitResults[multiPathResults.size()]);
    // Filter with no filter
    MultiPathFilter mpf = new MultiPathFilter(new SignalFilter(0), null, multiFilter.residualsThreshold);
    FractionClassificationResult fractionResult = mpf.fractionScoreSubset(multiResults, Integer.MAX_VALUE, this.results.size(), assignments, scoreStore, CoordinateStoreFactory.create(imp.getWidth(), imp.getHeight(), fitConfig.getDuplicateDistance()));
    double nPredicted = fractionResult.getTP() + fractionResult.getFP();
    final double[][] matchScores = new double[set.size()][];
    int count = 0;
    for (int i = 0; i < assignments.size(); i++) {
        FractionalAssignment[] a = assignments.get(i);
        if (a == null)
            continue;
        for (int j = 0; j < a.length; j++) {
            final PreprocessedPeakResult r = ((PeakFractionalAssignment) a[j]).peakResult;
            set.remove(r.getUniqueId());
            final double precision = Math.sqrt(r.getLocationVariance());
            final double signal = r.getSignal();
            final double snr = r.getSNR();
            final double width = r.getXSDFactor();
            final double xShift = r.getXRelativeShift2();
            final double yShift = r.getYRelativeShift2();
            // Since these two are combined for filtering and the max is what matters.
            final double shift = (xShift > yShift) ? Math.sqrt(xShift) : Math.sqrt(yShift);
            final double eshift = Math.sqrt(xShift + yShift);
            final double[] score = new double[8];
            score[FILTER_SIGNAL] = signal;
            score[FILTER_SNR] = snr;
            score[FILTER_MIN_WIDTH] = width;
            score[FILTER_MAX_WIDTH] = width;
            score[FILTER_SHIFT] = shift;
            score[FILTER_ESHIFT] = eshift;
            score[FILTER_PRECISION] = precision;
            score[FILTER_PRECISION + 1] = a[j].getScore();
            matchScores[count++] = score;
        }
    }
    // Add the rest
    set.forEach(new CustomTIntProcedure(count) {

        public boolean execute(int uniqueId) {
            // This should not be null or something has gone wrong
            PreprocessedPeakResult r = preprocessedPeakResults[uniqueId];
            if (r == null)
                throw new RuntimeException("Missing result: " + uniqueId);
            final double precision = Math.sqrt(r.getLocationVariance());
            final double signal = r.getSignal();
            final double snr = r.getSNR();
            final double width = r.getXSDFactor();
            final double xShift = r.getXRelativeShift2();
            final double yShift = r.getYRelativeShift2();
            // Since these two are combined for filtering and the max is what matters.
            final double shift = (xShift > yShift) ? Math.sqrt(xShift) : Math.sqrt(yShift);
            final double eshift = Math.sqrt(xShift + yShift);
            final double[] score = new double[8];
            score[FILTER_SIGNAL] = signal;
            score[FILTER_SNR] = snr;
            score[FILTER_MIN_WIDTH] = width;
            score[FILTER_MAX_WIDTH] = width;
            score[FILTER_SHIFT] = shift;
            score[FILTER_ESHIFT] = eshift;
            score[FILTER_PRECISION] = precision;
            matchScores[c++] = score;
            return true;
        }
    });
    // Debug the reasons the fit failed
    if (singleStatus != null) {
        String name = PeakFit.getSolverName(fitConfig);
        if (fitConfig.getFitSolver() == FitSolver.MLE && fitConfig.isModelCamera())
            name += " Camera";
        System.out.println("Failure counts: " + name);
        printFailures("Single", singleStatus);
        printFailures("Multi", multiStatus);
        printFailures("Doublet", doubletStatus);
        printFailures("Multi doublet", multiDoubletStatus);
    }
    StringBuilder sb = new StringBuilder(300);
    // Add information about the simulation
    //(simulationParameters.minSignal + simulationParameters.maxSignal) * 0.5;
    final double signal = simulationParameters.signalPerFrame;
    final int n = results.size();
    sb.append(imp.getStackSize()).append("\t");
    final int w = imp.getWidth();
    final int h = imp.getHeight();
    sb.append(w).append("\t");
    sb.append(h).append("\t");
    sb.append(n).append("\t");
    double density = ((double) n / imp.getStackSize()) / (w * h) / (simulationParameters.a * simulationParameters.a / 1e6);
    sb.append(Utils.rounded(density)).append("\t");
    sb.append(Utils.rounded(signal)).append("\t");
    sb.append(Utils.rounded(simulationParameters.s)).append("\t");
    sb.append(Utils.rounded(simulationParameters.a)).append("\t");
    sb.append(Utils.rounded(simulationParameters.depth)).append("\t");
    sb.append(simulationParameters.fixedDepth).append("\t");
    sb.append(Utils.rounded(simulationParameters.gain)).append("\t");
    sb.append(Utils.rounded(simulationParameters.readNoise)).append("\t");
    sb.append(Utils.rounded(simulationParameters.b)).append("\t");
    sb.append(Utils.rounded(simulationParameters.b2)).append("\t");
    // Compute the noise
    double noise = simulationParameters.b2;
    if (simulationParameters.emCCD) {
        // The b2 parameter was computed without application of the EM-CCD noise factor of 2.
        //final double b2 = backgroundVariance + readVariance
        //                = simulationParameters.b + readVariance
        // This should be applied only to the background variance.
        final double readVariance = noise - simulationParameters.b;
        noise = simulationParameters.b * 2 + readVariance;
    }
    if (simulationParameters.fullSimulation) {
    // The total signal is spread over frames
    }
    sb.append(Utils.rounded(signal / Math.sqrt(noise))).append("\t");
    sb.append(Utils.rounded(simulationParameters.s / simulationParameters.a)).append("\t");
    sb.append(spotFilter.getDescription());
    // nP and nN is the fractional score of the spot candidates 
    addCount(sb, nP + nN);
    addCount(sb, nP);
    addCount(sb, nN);
    addCount(sb, fP);
    addCount(sb, fN);
    String name = PeakFit.getSolverName(fitConfig);
    if (fitConfig.getFitSolver() == FitSolver.MLE && fitConfig.isModelCamera())
        name += " Camera";
    add(sb, name);
    add(sb, config.getFitting());
    resultPrefix = sb.toString();
    // Q. Should I add other fit configuration here?
    // The fraction of positive and negative candidates that were included
    add(sb, (100.0 * cTP) / nP);
    add(sb, (100.0 * cFP) / nN);
    // Score the fitting results compared to the original simulation.
    // Score the candidate selection:
    add(sb, cTP + cFP);
    add(sb, cTP);
    add(sb, cFP);
    // TP are all candidates that can be matched to a spot
    // FP are all candidates that cannot be matched to a spot
    // FN = The number of missed spots
    FractionClassificationResult m = new FractionClassificationResult(cTP, cFP, 0, simulationParameters.molecules - cTP);
    add(sb, m.getRecall());
    add(sb, m.getPrecision());
    add(sb, m.getF1Score());
    add(sb, m.getJaccard());
    // Score the fitting results:
    add(sb, failcTP);
    add(sb, failcFP);
    // TP are all fit results that can be matched to a spot
    // FP are all fit results that cannot be matched to a spot
    // FN = The number of missed spots
    add(sb, tp);
    add(sb, fp);
    m = new FractionClassificationResult(tp, fp, 0, simulationParameters.molecules - tp);
    add(sb, m.getRecall());
    add(sb, m.getPrecision());
    add(sb, m.getF1Score());
    add(sb, m.getJaccard());
    // Do it again but pretend we can perfectly filter all the false positives
    //add(sb, tp);
    m = new FractionClassificationResult(tp, 0, 0, simulationParameters.molecules - tp);
    // Recall is unchanged
    // Precision will be 100%
    add(sb, m.getF1Score());
    add(sb, m.getJaccard());
    // The mean may be subject to extreme outliers so use the median
    double median = distanceStats.getMedian();
    add(sb, median);
    WindowOrganiser wo = new WindowOrganiser();
    String label = String.format("Recall = %s. n = %d. Median = %s nm. SD = %s nm", Utils.rounded(m.getRecall()), distanceStats.getN(), Utils.rounded(median), Utils.rounded(distanceStats.getStandardDeviation()));
    int id = Utils.showHistogram(TITLE, distanceStats, "Match Distance (nm)", 0, 0, 0, label);
    if (Utils.isNewWindow())
        wo.add(id);
    median = depthStats.getMedian();
    add(sb, median);
    // Sort by spot intensity and produce correlation
    int[] indices = Utils.newArray(i1.length, 0, 1);
    if (showCorrelation)
        Sort.sort(indices, is, rankByIntensity);
    double[] r = (showCorrelation) ? new double[i1.length] : null;
    double[] sr = (showCorrelation) ? new double[i1.length] : null;
    double[] rank = (showCorrelation) ? new double[i1.length] : null;
    ci = 0;
    FastCorrelator fastCorrelator = new FastCorrelator();
    ArrayList<Ranking> pc1 = new ArrayList<Ranking>();
    ArrayList<Ranking> pc2 = new ArrayList<Ranking>();
    for (int ci2 : indices) {
        fastCorrelator.add((long) Math.round(i1[ci2]), (long) Math.round(i2[ci2]));
        pc1.add(new Ranking(i1[ci2], ci));
        pc2.add(new Ranking(i2[ci2], ci));
        if (showCorrelation) {
            r[ci] = fastCorrelator.getCorrelation();
            sr[ci] = Correlator.correlation(rank(pc1), rank(pc2));
            if (rankByIntensity)
                rank[ci] = is[0] - is[ci];
            else
                rank[ci] = ci;
        }
        ci++;
    }
    final double pearsonCorr = fastCorrelator.getCorrelation();
    final double rankedCorr = Correlator.correlation(rank(pc1), rank(pc2));
    // Get the regression
    SimpleRegression regression = new SimpleRegression(false);
    for (int i = 0; i < pc1.size(); i++) regression.addData(pc1.get(i).value, pc2.get(i).value);
    //final double intercept = regression.getIntercept();
    final double slope = regression.getSlope();
    if (showCorrelation) {
        String title = TITLE + " Intensity";
        Plot plot = new Plot(title, "Candidate", "Spot");
        double[] limits1 = Maths.limits(i1);
        double[] limits2 = Maths.limits(i2);
        plot.setLimits(limits1[0], limits1[1], limits2[0], limits2[1]);
        label = String.format("Correlation=%s; Ranked=%s; Slope=%s", Utils.rounded(pearsonCorr), Utils.rounded(rankedCorr), Utils.rounded(slope));
        plot.addLabel(0, 0, label);
        plot.setColor(Color.red);
        plot.addPoints(i1, i2, Plot.DOT);
        if (slope > 1)
            plot.drawLine(limits1[0], limits1[0] * slope, limits1[1], limits1[1] * slope);
        else
            plot.drawLine(limits2[0] / slope, limits2[0], limits2[1] / slope, limits2[1]);
        PlotWindow pw = Utils.display(title, plot);
        if (Utils.isNewWindow())
            wo.add(pw);
        title = TITLE + " Correlation";
        plot = new Plot(title, "Spot Rank", "Correlation");
        double[] xlimits = Maths.limits(rank);
        double[] ylimits = Maths.limits(r);
        ylimits = Maths.limits(ylimits, sr);
        plot.setLimits(xlimits[0], xlimits[1], ylimits[0], ylimits[1]);
        plot.setColor(Color.red);
        plot.addPoints(rank, r, Plot.LINE);
        plot.setColor(Color.blue);
        plot.addPoints(rank, sr, Plot.LINE);
        plot.setColor(Color.black);
        plot.addLabel(0, 0, label);
        pw = Utils.display(title, plot);
        if (Utils.isNewWindow())
            wo.add(pw);
    }
    add(sb, pearsonCorr);
    add(sb, rankedCorr);
    add(sb, slope);
    label = String.format("n = %d. Median = %s nm", depthStats.getN(), Utils.rounded(median));
    id = Utils.showHistogram(TITLE, depthStats, "Match Depth (nm)", 0, 1, 0, label);
    if (Utils.isNewWindow())
        wo.add(id);
    // Plot histograms of the stats on the same window
    double[] lower = new double[filterCriteria.length];
    double[] upper = new double[lower.length];
    min = new double[lower.length];
    max = new double[lower.length];
    for (int i = 0; i < stats[0].length; i++) {
        double[] limits = showDoubleHistogram(stats, i, wo, matchScores, nPredicted);
        lower[i] = limits[0];
        upper[i] = limits[1];
        min[i] = limits[2];
        max[i] = limits[3];
    }
    // Reconfigure some of the range limits
    // Make this a bit bigger
    upper[FILTER_SIGNAL] *= 2;
    // Make this a bit bigger
    upper[FILTER_SNR] *= 2;
    double factor = 0.25;
    if (lower[FILTER_MIN_WIDTH] != 0)
        // (assuming lower is less than 1)
        upper[FILTER_MIN_WIDTH] = 1 - Math.max(0, factor * (1 - lower[FILTER_MIN_WIDTH]));
    if (upper[FILTER_MIN_WIDTH] != 0)
        // (assuming upper is more than 1)
        lower[FILTER_MAX_WIDTH] = 1 + Math.max(0, factor * (upper[FILTER_MAX_WIDTH] - 1));
    // Round the ranges
    final double[] interval = new double[stats[0].length];
    interval[FILTER_SIGNAL] = SignalFilter.DEFAULT_INCREMENT;
    interval[FILTER_SNR] = SNRFilter.DEFAULT_INCREMENT;
    interval[FILTER_MIN_WIDTH] = WidthFilter2.DEFAULT_MIN_INCREMENT;
    interval[FILTER_MAX_WIDTH] = WidthFilter.DEFAULT_INCREMENT;
    interval[FILTER_SHIFT] = ShiftFilter.DEFAULT_INCREMENT;
    interval[FILTER_ESHIFT] = EShiftFilter.DEFAULT_INCREMENT;
    interval[FILTER_PRECISION] = PrecisionFilter.DEFAULT_INCREMENT;
    interval[FILTER_ITERATIONS] = 0.1;
    interval[FILTER_EVALUATIONS] = 0.1;
    // Create a range increment
    double[] increment = new double[lower.length];
    for (int i = 0; i < increment.length; i++) {
        lower[i] = Maths.floor(lower[i], interval[i]);
        upper[i] = Maths.ceil(upper[i], interval[i]);
        double range = upper[i] - lower[i];
        // Allow clipping if the range is small compared to the min increment
        double multiples = range / interval[i];
        // Use 8 multiples for the equivalent of +/- 4 steps around the centre
        if (multiples < 8) {
            multiples = Math.ceil(multiples);
        } else
            multiples = 8;
        increment[i] = Maths.ceil(range / multiples, interval[i]);
        if (i == FILTER_MIN_WIDTH)
            // Requires clipping based on the upper limit
            lower[i] = upper[i] - increment[i] * multiples;
        else
            upper[i] = lower[i] + increment[i] * multiples;
    }
    for (int i = 0; i < stats[0].length; i++) {
        lower[i] = Maths.round(lower[i]);
        upper[i] = Maths.round(upper[i]);
        min[i] = Maths.round(min[i]);
        max[i] = Maths.round(max[i]);
        increment[i] = Maths.round(increment[i]);
        sb.append("\t").append(min[i]).append(':').append(lower[i]).append('-').append(upper[i]).append(':').append(max[i]);
    }
    // Disable some filters
    increment[FILTER_SIGNAL] = Double.POSITIVE_INFINITY;
    //increment[FILTER_SHIFT] = Double.POSITIVE_INFINITY;
    increment[FILTER_ESHIFT] = Double.POSITIVE_INFINITY;
    wo.tile();
    sb.append("\t").append(Utils.timeToString(runTime / 1000000.0));
    summaryTable.append(sb.toString());
    if (saveFilterRange) {
        GlobalSettings gs = SettingsManager.loadSettings();
        FilterSettings filterSettings = gs.getFilterSettings();
        String filename = (silent) ? filterSettings.filterSetFilename : Utils.getFilename("Filter_range_file", filterSettings.filterSetFilename);
        if (filename == null)
            return;
        // Remove extension to store the filename
        filename = Utils.replaceExtension(filename, ".xml");
        filterSettings.filterSetFilename = filename;
        // Create a filter set using the ranges
        ArrayList<Filter> filters = new ArrayList<Filter>(3);
        filters.add(new MultiFilter2(lower[0], (float) lower[1], lower[2], lower[3], lower[4], lower[5], lower[6]));
        filters.add(new MultiFilter2(upper[0], (float) upper[1], upper[2], upper[3], upper[4], upper[5], upper[6]));
        filters.add(new MultiFilter2(increment[0], (float) increment[1], increment[2], increment[3], increment[4], increment[5], increment[6]));
        if (saveFilters(filename, filters))
            SettingsManager.saveSettings(gs);
        // Create a filter set using the min/max and the initial bounds.
        // Set sensible limits
        min[FILTER_SIGNAL] = Math.max(min[FILTER_SIGNAL], 30);
        max[FILTER_PRECISION] = Math.min(max[FILTER_PRECISION], 100);
        // Commented this out so that the 4-set filters are the same as the 3-set filters.
        // The difference leads to differences when optimising.
        //			// Use half the initial bounds (hoping this is a good starting guess for the optimum)
        //			final boolean[] limitToLower = new boolean[min.length];
        //			limitToLower[FILTER_SIGNAL] = true;
        //			limitToLower[FILTER_SNR] = true;
        //			limitToLower[FILTER_MIN_WIDTH] = true;
        //			limitToLower[FILTER_MAX_WIDTH] = false;
        //			limitToLower[FILTER_SHIFT] = false;
        //			limitToLower[FILTER_ESHIFT] = false;
        //			limitToLower[FILTER_PRECISION] = true;
        //			for (int i = 0; i < limitToLower.length; i++)
        //			{
        //				final double range = (upper[i] - lower[i]) / 2;
        //				if (limitToLower[i])
        //					upper[i] = lower[i] + range;
        //				else
        //					lower[i] = upper[i] - range;
        //			}
        filters = new ArrayList<Filter>(4);
        filters.add(new MultiFilter2(min[0], (float) min[1], min[2], min[3], min[4], min[5], min[6]));
        filters.add(new MultiFilter2(lower[0], (float) lower[1], lower[2], lower[3], lower[4], lower[5], lower[6]));
        filters.add(new MultiFilter2(upper[0], (float) upper[1], upper[2], upper[3], upper[4], upper[5], upper[6]));
        filters.add(new MultiFilter2(max[0], (float) max[1], max[2], max[3], max[4], max[5], max[6]));
        saveFilters(Utils.replaceExtension(filename, ".4.xml"), filters);
    }
}
Also used : ArrayList(java.util.ArrayList) TIntHashSet(gnu.trove.set.hash.TIntHashSet) MultiPathFitResult(gdsc.smlm.results.filter.MultiPathFitResult) FractionalAssignment(gdsc.core.match.FractionalAssignment) PeakFractionalAssignment(gdsc.smlm.results.filter.PeakFractionalAssignment) ImmutableFractionalAssignment(gdsc.core.match.ImmutableFractionalAssignment) FractionClassificationResult(gdsc.core.match.FractionClassificationResult) BasePreprocessedPeakResult(gdsc.smlm.results.filter.BasePreprocessedPeakResult) PreprocessedPeakResult(gdsc.smlm.results.filter.PreprocessedPeakResult) SignalFilter(gdsc.smlm.results.filter.SignalFilter) FilterSettings(gdsc.smlm.ij.settings.FilterSettings) ScoredSpot(gdsc.smlm.ij.plugins.BenchmarkSpotFilter.ScoredSpot) FastCorrelator(gdsc.core.utils.FastCorrelator) Plot(ij.gui.Plot) StoredDataStatistics(gdsc.core.utils.StoredDataStatistics) PlotWindow(ij.gui.PlotWindow) GlobalSettings(gdsc.smlm.ij.settings.GlobalSettings) WindowOrganiser(ij.plugin.WindowOrganiser) PeakResultPoint(gdsc.smlm.ij.plugins.ResultsMatchCalculator.PeakResultPoint) BasePoint(gdsc.core.match.BasePoint) PeakFractionalAssignment(gdsc.smlm.results.filter.PeakFractionalAssignment) FractionScoreStore(gdsc.smlm.results.filter.MultiPathFilter.FractionScoreStore) SimpleRegression(org.apache.commons.math3.stat.regression.SimpleRegression) SignalFilter(gdsc.smlm.results.filter.SignalFilter) DirectFilter(gdsc.smlm.results.filter.DirectFilter) ShiftFilter(gdsc.smlm.results.filter.ShiftFilter) PrecisionFilter(gdsc.smlm.results.filter.PrecisionFilter) Filter(gdsc.smlm.results.filter.Filter) EShiftFilter(gdsc.smlm.results.filter.EShiftFilter) WidthFilter(gdsc.smlm.results.filter.WidthFilter) SNRFilter(gdsc.smlm.results.filter.SNRFilter) MultiPathFilter(gdsc.smlm.results.filter.MultiPathFilter) MaximaSpotFilter(gdsc.smlm.filters.MaximaSpotFilter) MultiFilter2(gdsc.smlm.results.filter.MultiFilter2) MultiPathFitResults(gdsc.smlm.results.filter.MultiPathFitResults) MultiPathFilter(gdsc.smlm.results.filter.MultiPathFilter)

Example 58 with Max

use of org.apache.commons.math3.stat.descriptive.rank.Max in project GDSC-SMLM by aherbert.

the class BenchmarkSpotFit method showDoubleHistogram.

private double[] showDoubleHistogram(StoredDataStatistics[][] stats, final int i, WindowOrganiser wo, double[][] matchScores, double nPredicted) {
    String xLabel = filterCriteria[i].name;
    LowerLimit lower = filterCriteria[i].lower;
    UpperLimit upper = filterCriteria[i].upper;
    double[] j = null;
    double[] metric = null;
    double maxJ = 0;
    if (i <= FILTER_PRECISION && (showFilterScoreHistograms || upper.requiresJaccard || lower.requiresJaccard)) {
        // Jaccard score verses the range of the metric
        Arrays.sort(matchScores, new Comparator<double[]>() {

            public int compare(double[] o1, double[] o2) {
                if (o1[i] < o2[i])
                    return -1;
                if (o1[i] > o2[i])
                    return 1;
                return 0;
            }
        });
        final int scoreIndex = FILTER_PRECISION + 1;
        int n = results.size();
        double tp = 0;
        double fp = 0;
        j = new double[matchScores.length + 1];
        metric = new double[j.length];
        for (int k = 0; k < matchScores.length; k++) {
            final double score = matchScores[k][scoreIndex];
            tp += score;
            fp += (1 - score);
            j[k + 1] = tp / (fp + n);
            metric[k + 1] = matchScores[k][i];
        }
        metric[0] = metric[1];
        maxJ = Maths.max(j);
        if (showFilterScoreHistograms) {
            String title = TITLE + " Jaccard " + xLabel;
            Plot plot = new Plot(title, xLabel, "Jaccard", metric, j);
            // Remove outliers
            double[] limitsx = Maths.limits(metric);
            Percentile p = new Percentile();
            double l = p.evaluate(metric, 25);
            double u = p.evaluate(metric, 75);
            double iqr = 1.5 * (u - l);
            limitsx[1] = Math.min(limitsx[1], u + iqr);
            plot.setLimits(limitsx[0], limitsx[1], 0, Maths.max(j));
            PlotWindow pw = Utils.display(title, plot);
            if (Utils.isNewWindow())
                wo.add(pw);
        }
    }
    // [0] is all
    // [1] is matches
    // [2] is no match
    StoredDataStatistics s1 = stats[0][i];
    StoredDataStatistics s2 = stats[1][i];
    StoredDataStatistics s3 = stats[2][i];
    if (s1.getN() == 0)
        return new double[4];
    DescriptiveStatistics d = s1.getStatistics();
    double median = 0;
    Plot2 plot = null;
    String title = null;
    if (showFilterScoreHistograms) {
        median = d.getPercentile(50);
        String label = String.format("n = %d. Median = %s nm", s1.getN(), Utils.rounded(median));
        int id = Utils.showHistogram(TITLE, s1, xLabel, filterCriteria[i].minBinWidth, (filterCriteria[i].restrictRange) ? 1 : 0, 0, label);
        if (id == 0) {
            IJ.log("Failed to show the histogram: " + xLabel);
            return new double[4];
        }
        if (Utils.isNewWindow())
            wo.add(id);
        title = WindowManager.getImage(id).getTitle();
        // Reverse engineer the histogram settings
        plot = Utils.plot;
        double[] xValues = Utils.xValues;
        int bins = xValues.length;
        double yMin = xValues[0];
        double binSize = xValues[1] - xValues[0];
        double yMax = xValues[0] + (bins - 1) * binSize;
        if (s2.getN() > 0) {
            double[] values = s2.getValues();
            double[][] hist = Utils.calcHistogram(values, yMin, yMax, bins);
            if (hist[0].length > 0) {
                plot.setColor(Color.red);
                plot.addPoints(hist[0], hist[1], Plot2.BAR);
                Utils.display(title, plot);
            }
        }
        if (s3.getN() > 0) {
            double[] values = s3.getValues();
            double[][] hist = Utils.calcHistogram(values, yMin, yMax, bins);
            if (hist[0].length > 0) {
                plot.setColor(Color.blue);
                plot.addPoints(hist[0], hist[1], Plot2.BAR);
                Utils.display(title, plot);
            }
        }
    }
    // Do cumulative histogram
    double[][] h1 = Maths.cumulativeHistogram(s1.getValues(), true);
    double[][] h2 = Maths.cumulativeHistogram(s2.getValues(), true);
    double[][] h3 = Maths.cumulativeHistogram(s3.getValues(), true);
    if (showFilterScoreHistograms) {
        title = TITLE + " Cumul " + xLabel;
        plot = new Plot2(title, xLabel, "Frequency");
        // Find limits
        double[] xlimit = Maths.limits(h1[0]);
        xlimit = Maths.limits(xlimit, h2[0]);
        xlimit = Maths.limits(xlimit, h3[0]);
        // Restrict using the inter-quartile range 
        if (filterCriteria[i].restrictRange) {
            double q1 = d.getPercentile(25);
            double q2 = d.getPercentile(75);
            double iqr = (q2 - q1) * 2.5;
            xlimit[0] = Maths.max(xlimit[0], median - iqr);
            xlimit[1] = Maths.min(xlimit[1], median + iqr);
        }
        plot.setLimits(xlimit[0], xlimit[1], 0, 1.05);
        plot.addPoints(h1[0], h1[1], Plot.LINE);
        plot.setColor(Color.red);
        plot.addPoints(h2[0], h2[1], Plot.LINE);
        plot.setColor(Color.blue);
        plot.addPoints(h3[0], h3[1], Plot.LINE);
    }
    // Determine the maximum difference between the TP and FP
    double maxx1 = 0;
    double maxx2 = 0;
    double max1 = 0;
    double max2 = 0;
    // We cannot compute the delta histogram, or use percentiles
    if (s2.getN() == 0) {
        upper = UpperLimit.ZERO;
        lower = LowerLimit.ZERO;
    }
    final boolean requireLabel = (showFilterScoreHistograms && filterCriteria[i].requireLabel);
    if (requireLabel || upper.requiresDeltaHistogram() || lower.requiresDeltaHistogram()) {
        if (s2.getN() != 0 && s3.getN() != 0) {
            LinearInterpolator li = new LinearInterpolator();
            PolynomialSplineFunction f1 = li.interpolate(h2[0], h2[1]);
            PolynomialSplineFunction f2 = li.interpolate(h3[0], h3[1]);
            for (double x : h1[0]) {
                if (x < h2[0][0] || x < h3[0][0])
                    continue;
                try {
                    double v1 = f1.value(x);
                    double v2 = f2.value(x);
                    double diff = v2 - v1;
                    if (diff > 0) {
                        if (max1 < diff) {
                            max1 = diff;
                            maxx1 = x;
                        }
                    } else {
                        if (max2 > diff) {
                            max2 = diff;
                            maxx2 = x;
                        }
                    }
                } catch (OutOfRangeException e) {
                    // Because we reached the end
                    break;
                }
            }
        } else {
            // Switch to percentiles if we have no delta histogram
            if (upper.requiresDeltaHistogram())
                upper = UpperLimit.NINETY_NINE_PERCENT;
            if (lower.requiresDeltaHistogram())
                lower = LowerLimit.ONE_PERCENT;
        }
    //			System.out.printf("Bounds %s : %s, pos %s, neg %s, %s\n", xLabel, Utils.rounded(getPercentile(h2, 0.01)),
    //					Utils.rounded(maxx1), Utils.rounded(maxx2), Utils.rounded(getPercentile(h1, 0.99)));
    }
    if (showFilterScoreHistograms) {
        // We use bins=1 on charts where we do not need a label
        if (requireLabel) {
            String label = String.format("Max+ %s @ %s, Max- %s @ %s", Utils.rounded(max1), Utils.rounded(maxx1), Utils.rounded(max2), Utils.rounded(maxx2));
            plot.setColor(Color.black);
            plot.addLabel(0, 0, label);
        }
        PlotWindow pw = Utils.display(title, plot);
        if (Utils.isNewWindow())
            wo.add(pw.getImagePlus().getID());
    }
    // Now compute the bounds using the desired limit
    double l, u;
    switch(lower) {
        case ONE_PERCENT:
            l = getPercentile(h2, 0.01);
            break;
        case MAX_NEGATIVE_CUMUL_DELTA:
            l = maxx2;
            break;
        case ZERO:
            l = 0;
            break;
        case HALF_MAX_JACCARD_VALUE:
            l = getValue(metric, j, maxJ * 0.5);
            break;
        default:
            throw new RuntimeException("Missing lower limit method");
    }
    switch(upper) {
        case MAX_POSITIVE_CUMUL_DELTA:
            u = maxx1;
            break;
        case NINETY_NINE_PERCENT:
            u = getPercentile(h2, 0.99);
            break;
        case NINETY_NINE_NINE_PERCENT:
            u = getPercentile(h2, 0.999);
            break;
        case ZERO:
            u = 0;
            break;
        case MAX_JACCARD2:
            u = getValue(metric, j, maxJ) * 2;
            //System.out.printf("MaxJ = %.4f @ %.3f\n", maxJ, u / 2);
            break;
        default:
            throw new RuntimeException("Missing upper limit method");
    }
    double min = getPercentile(h1, 0);
    double max = getPercentile(h1, 1);
    return new double[] { l, u, min, max };
}
Also used : DescriptiveStatistics(org.apache.commons.math3.stat.descriptive.DescriptiveStatistics) Percentile(org.apache.commons.math3.stat.descriptive.rank.Percentile) Plot(ij.gui.Plot) StoredDataStatistics(gdsc.core.utils.StoredDataStatistics) PlotWindow(ij.gui.PlotWindow) Plot2(ij.gui.Plot2) PolynomialSplineFunction(org.apache.commons.math3.analysis.polynomials.PolynomialSplineFunction) PeakResultPoint(gdsc.smlm.ij.plugins.ResultsMatchCalculator.PeakResultPoint) BasePoint(gdsc.core.match.BasePoint) LinearInterpolator(org.apache.commons.math3.analysis.interpolation.LinearInterpolator) OutOfRangeException(org.apache.commons.math3.exception.OutOfRangeException)

Example 59 with Max

use of org.apache.commons.math3.stat.descriptive.rank.Max in project GDSC-SMLM by aherbert.

the class BenchmarkSpotFilter method summariseResults.

private BenchmarkFilterResult summariseResults(TIntObjectHashMap<FilterResult> filterResults, FitEngineConfiguration config, MaximaSpotFilter spotFilter, boolean relativeDistances, boolean batchSummary) {
    BenchmarkFilterResult filterResult = new BenchmarkFilterResult(filterResults, config, spotFilter);
    // Note: 
    // Although we can compute the TP/FP score as each additional spot is added
    // using the RankedScoreCalculator this is not applicable to the PeakFit method.
    // The method relies on all spot candidates being present in order to make a
    // decision to fit the candidate as a multiple. So scoring the filter candidates using
    // for example the top 10 may get a better score than if all candidates were scored
    // and the scores accumulated for the top 10, it is not how the algorithm will use the 
    // candidate set. I.e. It does not use the top 10, then top 20 to refine the fit, etc. 
    // (the method is not iterative) .
    // We require an assessment of how a subset of the scored candidates
    // in ranked order contributes to the overall score, i.e. are the candidates ranked
    // in the correct order, those most contributing to the match to the underlying data 
    // should be higher up and those least contributing will be at the end.
    // TODO We could add some smart filtering of candidates before ranking. This would
    // allow assessment of the candidate set handed to PeakFit. E.g. Threshold the image
    // and only use candidates that are in the foreground region.
    double[][] cumul = histogramFailures(filterResult);
    // Create the overall match score
    final double[] total = new double[3];
    final ArrayList<ScoredSpot> allSpots = new ArrayList<BenchmarkSpotFilter.ScoredSpot>();
    filterResults.forEachValue(new TObjectProcedure<FilterResult>() {

        public boolean execute(FilterResult result) {
            total[0] += result.result.getTP();
            total[1] += result.result.getFP();
            total[2] += result.result.getFN();
            allSpots.addAll(Arrays.asList(result.spots));
            return true;
        }
    });
    double tp = total[0], fp = total[1], fn = total[2];
    FractionClassificationResult allResult = new FractionClassificationResult(tp, fp, 0, fn);
    // The number of actual results
    final double n = (tp + fn);
    StringBuilder sb = new StringBuilder();
    double signal = (simulationParameters.minSignal + simulationParameters.maxSignal) * 0.5;
    // Create the benchmark settings and the fitting settings
    sb.append(imp.getStackSize()).append("\t");
    final int w = lastAnalysisBorder.width;
    final int h = lastAnalysisBorder.height;
    sb.append(w).append("\t");
    sb.append(h).append("\t");
    sb.append(Utils.rounded(n)).append("\t");
    double density = (n / imp.getStackSize()) / (w * h) / (simulationParameters.a * simulationParameters.a / 1e6);
    sb.append(Utils.rounded(density)).append("\t");
    sb.append(Utils.rounded(signal)).append("\t");
    sb.append(Utils.rounded(simulationParameters.s)).append("\t");
    sb.append(Utils.rounded(simulationParameters.a)).append("\t");
    sb.append(Utils.rounded(simulationParameters.depth)).append("\t");
    sb.append(simulationParameters.fixedDepth).append("\t");
    sb.append(Utils.rounded(simulationParameters.gain)).append("\t");
    sb.append(Utils.rounded(simulationParameters.readNoise)).append("\t");
    sb.append(Utils.rounded(simulationParameters.b)).append("\t");
    sb.append(Utils.rounded(simulationParameters.b2)).append("\t");
    // Compute the noise
    double noise = simulationParameters.b2;
    if (simulationParameters.emCCD) {
        // The b2 parameter was computed without application of the EM-CCD noise factor of 2.
        //final double b2 = backgroundVariance + readVariance
        //                = simulationParameters.b + readVariance
        // This should be applied only to the background variance.
        final double readVariance = noise - simulationParameters.b;
        noise = simulationParameters.b * 2 + readVariance;
    }
    sb.append(Utils.rounded(signal / Math.sqrt(noise))).append("\t");
    sb.append(Utils.rounded(simulationParameters.s / simulationParameters.a)).append("\t");
    sb.append(config.getDataFilterType()).append("\t");
    //sb.append(spotFilter.getName()).append("\t");
    sb.append(spotFilter.getSearch()).append("\t");
    sb.append(spotFilter.getBorder()).append("\t");
    sb.append(Utils.rounded(spotFilter.getSpread())).append("\t");
    sb.append(config.getDataFilter(0)).append("\t");
    final double param = config.getSmooth(0);
    final double hwhmMin = config.getHWHMMin();
    if (relativeDistances) {
        sb.append(Utils.rounded(param * hwhmMin)).append("\t");
        sb.append(Utils.rounded(param)).append("\t");
    } else {
        sb.append(Utils.rounded(param)).append("\t");
        sb.append(Utils.rounded(param / hwhmMin)).append("\t");
    }
    sb.append(spotFilter.getDescription()).append("\t");
    sb.append(lastAnalysisBorder.x).append("\t");
    sb.append(MATCHING_METHOD[matchingMethod]).append("\t");
    sb.append(Utils.rounded(lowerMatchDistance)).append("\t");
    sb.append(Utils.rounded(matchDistance)).append("\t");
    sb.append(Utils.rounded(lowerSignalFactor)).append("\t");
    sb.append(Utils.rounded(upperSignalFactor));
    resultPrefix = sb.toString();
    // Add the results
    sb.append("\t");
    // Rank the scored spots by intensity
    Collections.sort(allSpots);
    // Produce Recall, Precision, Jaccard for each cut of the spot candidates
    double[] r = new double[allSpots.size() + 1];
    double[] p = new double[r.length];
    double[] j = new double[r.length];
    double[] c = new double[r.length];
    double[] truePositives = new double[r.length];
    double[] falsePositives = new double[r.length];
    double[] intensity = new double[r.length];
    // Note: fn = n - tp
    tp = fp = 0;
    int i = 1;
    p[0] = 1;
    FastCorrelator corr = new FastCorrelator();
    double lastC = 0;
    double[] i1 = new double[r.length];
    double[] i2 = new double[r.length];
    int ci = 0;
    SimpleRegression regression = new SimpleRegression(false);
    for (ScoredSpot s : allSpots) {
        if (s.match) {
            // Score partial matches as part true-positive and part false-positive.
            // TP can be above 1 if we are allowing multiple matches.
            tp += s.getScore();
            fp += s.antiScore();
            // Just use a rounded intensity for now
            final double spotIntensity = s.getIntensity();
            final long v1 = (long) Math.round(spotIntensity);
            final long v2 = (long) Math.round(s.intensity);
            regression.addData(spotIntensity, s.intensity);
            i1[ci] = spotIntensity;
            i2[ci] = s.intensity;
            ci++;
            corr.add(v1, v2);
            lastC = corr.getCorrelation();
        } else
            fp++;
        r[i] = (double) tp / n;
        p[i] = (double) tp / (tp + fp);
        // (tp+fp+fn) == (fp+n) since tp+fn=n;
        j[i] = (double) tp / (fp + n);
        c[i] = lastC;
        truePositives[i] = tp;
        falsePositives[i] = fp;
        intensity[i] = s.getIntensity();
        i++;
    }
    i1 = Arrays.copyOf(i1, ci);
    i2 = Arrays.copyOf(i2, ci);
    final double slope = regression.getSlope();
    sb.append(Utils.rounded(slope)).append("\t");
    addResult(sb, allResult, c[c.length - 1]);
    // Output the match results when the recall achieves the fraction of the maximum.
    double target = r[r.length - 1];
    if (recallFraction < 100)
        target *= recallFraction / 100.0;
    int fractionIndex = 0;
    while (fractionIndex < r.length && r[fractionIndex] < target) {
        fractionIndex++;
    }
    if (fractionIndex == r.length)
        fractionIndex--;
    addResult(sb, new FractionClassificationResult(truePositives[fractionIndex], falsePositives[fractionIndex], 0, n - truePositives[fractionIndex]), c[fractionIndex]);
    // Output the match results at the maximum jaccard score
    int maxIndex = 0;
    for (int ii = 1; ii < r.length; ii++) {
        if (j[maxIndex] < j[ii])
            maxIndex = ii;
    }
    addResult(sb, new FractionClassificationResult(truePositives[maxIndex], falsePositives[maxIndex], 0, n - truePositives[maxIndex]), c[maxIndex]);
    sb.append(Utils.rounded(time / 1e6));
    // Calculate AUC (Average precision == Area Under Precision-Recall curve)
    final double auc = AUCCalculator.auc(p, r);
    // Compute the AUC using the adjusted precision curve
    // which uses the maximum precision for recall >= r
    final double[] maxp = new double[p.length];
    double max = 0;
    for (int k = maxp.length; k-- > 0; ) {
        if (max < p[k])
            max = p[k];
        maxp[k] = max;
    }
    final double auc2 = AUCCalculator.auc(maxp, r);
    sb.append("\t").append(Utils.rounded(auc));
    sb.append("\t").append(Utils.rounded(auc2));
    // Output the number of fit failures that must be processed to capture fractions of the true positives
    if (cumul[0].length != 0) {
        sb.append("\t").append(Utils.rounded(getFailures(cumul, 0.80)));
        sb.append("\t").append(Utils.rounded(getFailures(cumul, 0.90)));
        sb.append("\t").append(Utils.rounded(getFailures(cumul, 0.95)));
        sb.append("\t").append(Utils.rounded(getFailures(cumul, 0.99)));
        sb.append("\t").append(Utils.rounded(cumul[0][cumul[0].length - 1]));
    } else
        sb.append("\t\t\t\t\t");
    BufferedTextWindow resultsTable = getTable(batchSummary);
    resultsTable.append(sb.toString());
    // Store results
    filterResult.auc = auc;
    filterResult.auc2 = auc2;
    filterResult.r = r;
    filterResult.p = p;
    filterResult.j = j;
    filterResult.c = c;
    filterResult.maxIndex = maxIndex;
    filterResult.fractionIndex = fractionIndex;
    filterResult.cumul = cumul;
    filterResult.slope = slope;
    filterResult.i1 = i1;
    filterResult.i2 = i2;
    filterResult.intensity = intensity;
    filterResult.relativeDistances = relativeDistances;
    filterResult.time = time;
    return filterResult;
}
Also used : BufferedTextWindow(gdsc.core.ij.BufferedTextWindow) FastCorrelator(gdsc.core.utils.FastCorrelator) ArrayList(java.util.ArrayList) PeakResultPoint(gdsc.smlm.ij.plugins.ResultsMatchCalculator.PeakResultPoint) BasePoint(gdsc.core.match.BasePoint) SimpleRegression(org.apache.commons.math3.stat.regression.SimpleRegression) FractionClassificationResult(gdsc.core.match.FractionClassificationResult)

Example 60 with Max

use of org.apache.commons.math3.stat.descriptive.rank.Max in project lucene-solr by apache.

the class EmpiricalDistributionEvaluator method evaluate.

public Tuple evaluate(Tuple tuple) throws IOException {
    if (subEvaluators.size() != 1) {
        throw new IOException("Empirical dist expects 1 column as a parameters");
    }
    StreamEvaluator colEval1 = subEvaluators.get(0);
    List<Number> numbers1 = (List<Number>) colEval1.evaluate(tuple);
    double[] column1 = new double[numbers1.size()];
    for (int i = 0; i < numbers1.size(); i++) {
        column1[i] = numbers1.get(i).doubleValue();
    }
    Arrays.sort(column1);
    EmpiricalDistribution empiricalDistribution = new EmpiricalDistribution();
    empiricalDistribution.load(column1);
    Map map = new HashMap();
    StatisticalSummary statisticalSummary = empiricalDistribution.getSampleStats();
    map.put("max", statisticalSummary.getMax());
    map.put("mean", statisticalSummary.getMean());
    map.put("min", statisticalSummary.getMin());
    map.put("stdev", statisticalSummary.getStandardDeviation());
    map.put("sum", statisticalSummary.getSum());
    map.put("N", statisticalSummary.getN());
    map.put("var", statisticalSummary.getVariance());
    return new EmpiricalDistributionTuple(empiricalDistribution, column1, map);
}
Also used : EmpiricalDistribution(org.apache.commons.math3.random.EmpiricalDistribution) StatisticalSummary(org.apache.commons.math3.stat.descriptive.StatisticalSummary) HashMap(java.util.HashMap) List(java.util.List) IOException(java.io.IOException) HashMap(java.util.HashMap) Map(java.util.Map)

Aggregations

ArrayList (java.util.ArrayList)26 List (java.util.List)19 Collectors (java.util.stream.Collectors)13 DescriptiveStatistics (org.apache.commons.math3.stat.descriptive.DescriptiveStatistics)13 Arrays (java.util.Arrays)11 Map (java.util.Map)11 IntStream (java.util.stream.IntStream)10 RandomGenerator (org.apache.commons.math3.random.RandomGenerator)10 Array2DRowRealMatrix (org.apache.commons.math3.linear.Array2DRowRealMatrix)9 RealMatrix (org.apache.commons.math3.linear.RealMatrix)9 Plot2 (ij.gui.Plot2)8 File (java.io.File)8 IOException (java.io.IOException)8 TooManyEvaluationsException (org.apache.commons.math3.exception.TooManyEvaluationsException)7 Test (org.testng.annotations.Test)7 StoredDataStatistics (gdsc.core.utils.StoredDataStatistics)6 Collections (java.util.Collections)6 HashMap (java.util.HashMap)6 Random (java.util.Random)6 UnivariateFunction (org.apache.commons.math3.analysis.UnivariateFunction)6