def makeXCorr(self, spk_times: np.array, ax: matplotlib.axes = None, **kwargs) -> matplotlib.axes: # spk_times in samples provided in seconds but convert to # ms for a more display friendly scale spk_times = spk_times / 3e4 * 1000. S = SpikeCalcsGeneric(spk_times) y = S.xcorr(spk_times) if ax is None: fig = plt.figure() ax = fig.add_subplot(111) ax.hist( y[y != 0], bins=201, range=[-500, 500], color='k', histtype='stepfilled') ax.set_xlim(-500, 500) ax.set_xticks((-500, 0, 500)) ax.set_xticklabels('') ax.tick_params( axis='both', which='both', left=False, right=False, bottom=False, top=False) ax.set_yticklabels('') ax.spines['right'].set_visible(False) ax.spines['top'].set_visible(False) ax.spines['left'].set_visible(False) ax.xaxis.set_ticks_position('bottom') return ax
def plot_openness_by_hour(data: list, period: dict, ax: Axes): """ Plots the openness by hour from the raw data. :param data: Raw data :param period: Period over which to average the openness :param ax: Axes object in which to put the plot :return: None """ num_hrs = 24 # Get data hour_bins = get_openness_by_hour(data, period) # Plot bar chart ax.bar(range(num_hrs + 1), hour_bins) # Decorate the axes ax.yaxis.grid(True, which="both", linestyle="-.") ax.set_xlim(1, num_hrs) ax.set_xticks(range(num_hrs + 1)) ax.set_xticklabels([f"{t:02d}" for t in ax.get_xticks()]) ax.set_yticklabels([f"{o * 100:.1f}{percent()}" for o in ax.get_yticks()]) ax.set_ylabel("Andel åpen") ax.set_xlabel("Tid på døgnet")
def plot_chromatograph( seq: SeqRecord, region: Tuple[int, int] = None, ax: mpl.axes = None ) -> plt.axes: """Plot Sanger chromatograph. region: include both start and end (1-based) """ if seq is None: return ax if region is None: # turn into 0 based for better indexing region_start, region_end = 0, len(seq) else: region_start = max(region[0], 0) region_end = min(region[1], len(seq) - 1) if ax is None: _, ax = plt.subplots(1, 1, figsize=(16, 6)) _colors = defaultdict( lambda: "purple", {"A": "g", "C": "b", "G": "k", "T": "r"} ) # Get signals peaks = seq.annotations["peak positions"] trace_x = seq.annotations["trace_x"] traces_y = [seq.annotations["channel " + str(i)] for i in range(1, 5)] bases = seq.annotations["channels"] xlim_left, xlim_right = peaks[region_start] - 1, peaks[region_end] + 0.5 # subset peak and sequence # TODO: this might fix the bug peak_start = peaks[0] peak_zip = [ (p, s) for i, (p, s) in enumerate(zip(peaks, seq)) if region_start <= i <= region_end ] peaks, seq = list(zip(*peak_zip)) # subset trace_x and traces_y together trace_zip = [ (x + peak_start, *ys) for x, *ys in zip(trace_x, *traces_y) if xlim_left <= x <= xlim_right ] if not trace_zip: return ax trace_x, *traces_y = list(zip(*trace_zip)) # Plot traces trmax = max(map(max, traces_y)) for base in bases: trace_y = [1.0 * ci / trmax for ci in traces_y[bases.index(base)]] ax.plot(trace_x, trace_y, color=_colors[base], lw=2, label=base) ax.fill_between( trace_x, 0, trace_y, facecolor=_colors[base], alpha=0.125 ) # Plot bases at peak positions for i, peak in enumerate(peaks): # LOGGER.debug(f"{i}, {peak}, {seq[i]}, {xlim_left + i}") ax.text( peak, -0.11, seq[i], color=_colors[seq[i]], va="center", ha="center", alpha=0.66, fontsize="x-large", fontweight="bold", ) ax.set_ylim(bottom=-0.15, top=1.05) # peaks[0] - max(2, 0.02 * (peaks[-1] - peaks[0])), # right=peaks[-1] + max(2, 0.02 * (peaks[-1] - peaks[0])), ax.set_xlim(xlim_left + 0.5, xlim_right) ax.set_xticks(peaks) ax.set_xticklabels(list(range(region_start + 1, region_end + 2))) # hide y axis ax.set_yticklabels([]) ax.get_yaxis().set_visible(False) # hide border ax.spines["left"].set_visible(False) ax.spines["right"].set_visible(False) ax.spines["top"].set_visible(False) # hide grid ax.grid(False) # set legend ax.legend(loc="upper left", bbox_to_anchor=(0.95, 0.99)) return ax
def cohort_bar(cohort_averages: dict, cohort_data: dict, observable: str, yaxis_upper: int = None, ax: matplotlib.axes = None, labelsize: int = 12, ticksize: int = 10, legendsize: int = 8, markersize=15) -> None: """Plots either the V- or J-gene usages. Parameters ---------- cohort_averages : dict Dictionary of averages and variations within a cohort for all severities. cohort_dict : dict Dictionary of all statistics of all individuals in a cohort for all severities. observable : str The quantity which is going to be plotted. yaxis_upper : int, optional Specifies the upper limit of the y-axis on the plot. ax : matplotlib.axes, optional Used to modify an already existing axes when creating a figure with a grid. labelsize : int, optional Size of axes labels. ticksize : int, optional Size of tick labels. legendsize : int, optional Specifies font size of strings in legend. Returns ------- None """ if ax is None: fig = plt.figure(dpi=300, figsize=(16, 4)) ax = fig.add_subplot(111) # Give the bars for each gene some space among each other. width = 1.0 / len(cohort_averages) - 0.02 bars = [] if 'Asymptomatic' in cohort_averages: ordering = ['Healthy', 'Mild', 'Moderate', 'Severe', 'Asymptomatic'] else: ordering = sorted(cohort_averages.keys()) # Sort the genes by descending usage in the healthy cohort. if 'Briney/GRP' in cohort_averages: sorted_genes = [ gene for _, gene in sorted(zip( cohort_averages['Briney/GRP'][observable][0], cohort_averages['Briney/GRP'][observable][-1]), key=lambda pair: pair[0], reverse=True) ] else: sorted_genes = [ gene for _, gene in sorted(zip( cohort_averages['Healthy'][observable][0], cohort_averages['Healthy'][observable][-1]), key=lambda pair: pair[0], reverse=True) ] # Because there are so many V genes, plot only those which have at least # 1% average usage in at least one cohort. if 'v' in observable: good_genes = [] for gene in sorted_genes: bools = 0 for severity in cohort_averages: idx = cohort_averages[severity][observable][-1].index(gene) value = cohort_averages[severity][observable][0][idx] bools += value >= 0.01 if bools != 0: good_genes.append(gene) else: good_genes = sorted_genes xlabels = good_genes default_x = np.arange(0, len(good_genes), 1) xs, ys = [], [] for i, severity in enumerate(ordering): x = default_x + width * i xs.append(x) indices = [ cohort_averages[severity][observable][-1].index(gene) for gene in good_genes ] y = [cohort_averages[severity][observable][0][k] for k in indices] ys.append(y) if observable == 'v gene': ax.set_xlim(-0.3, xs[0][-1] + 1.0) if yaxis_upper is not None: ax.set_ylim(0, yaxis_upper) else: ax.set_ylim(0, 0.35) else: ax.set_xlim(-0.3, xs[0][-1] + 1.0) if yaxis_upper is not None: ax.set_ylim(0, yaxis_upper) else: ax.set_ylim(0, 0.55) # Specifiy location of xticks as being in the middle of the grouping of bars. middle = np.mean(np.arange(0, len(cohort_averages))) middle_xticks = default_x + middle * width ax.set_xticks(middle_xticks) ax.set_xticklabels(xlabels, rotation=90, family='Arial') ax.set_ylabel('relative counts', fontname="Arial") # Plot the bars. for i, severity in enumerate(ordering): bar = ax.bar(xs[i], ys[i], width, color=colors[severity], label=severity) for d in cohort_data[severity][observable]: # Plot the full distributions of values to get a better sense # of variation within cohorts. for gidx, rect in enumerate(bar): ax.scatter(xs[i][gidx], d[good_genes[gidx]], marker='.', color=lightercolors[severity], zorder=3, s=markersize, edgecolors='black', linewidths=0.3) format_axes(ax, labelsize=labelsize, ticksize=ticksize, legendsize=legendsize)