fire

code/chirpdetection.py

@@ -198,7 +198,7 @@ class ChirpPlotBuffer:
             for chirp in chirps:
                 ax0.scatter(
                     chirp, np.median(self.frequency), c=ps.red, marker=".",
-                    edgecolors=ps.red,
+                    edgecolors=ps.black,
                     facecolors=ps.red,
                     zorder=10,
                     s=70,
@@ -226,7 +226,7 @@ class ChirpPlotBuffer:
         ax4.scatter(
             (self.time)[self.baseline_peaks],
             (self.baseline_envelope*waveform_scaler)[self.baseline_peaks],
-            edgecolors=ps.red,
+            edgecolors=ps.black,
             facecolors=ps.red,
             zorder=10,
             marker=".",
@@ -240,7 +240,7 @@ class ChirpPlotBuffer:
         ax5.scatter(
             (self.time)[self.search_peaks],
             (self.search_envelope*waveform_scaler)[self.search_peaks],
-            edgecolors=ps.red,
+            edgecolors=ps.black,
             facecolors=ps.red,
             zorder=10,
             marker=".",
@@ -254,7 +254,7 @@ class ChirpPlotBuffer:
         ax6.scatter(
             self.frequency_time[self.frequency_peaks],
             self.frequency_filtered[self.frequency_peaks],
-            edgecolors=ps.red,
+            edgecolors=ps.black,
             facecolors=ps.red,
             zorder=10,
             marker=".",

code/modules/plotstyle.py

@@ -26,14 +26,14 @@ def PlotStyle() -> None:
         yellow = "#f9d67f"
         orange = "#faa472"
         maroon = "#eb8486"
-        red = "#f37588"
+        red = "#e0e4f7"
         purple = "#d89bf7"
         pink = "#f59edb"
         lavender = "#b4befe"
-        gblue1 = "#89b4fa"
-        gblue2 = "#89dceb"
-        gblue3 = "#a6e3a1"
-        g = "#76a0fa"
+        gblue1 = "#f37588"
+        gblue2 = "#faa472"
+        gblue3 = "#f9d67f"
+        g = "#f3626c"
 
         @classmethod
         def lims(cls, track1, track2):
@@ -230,7 +230,7 @@ def PlotStyle() -> None:
     plt.rc("legend", fontsize=SMALL_SIZE)  # legend fontsize
     plt.rc("figure", titlesize=BIGGER_SIZE)  # fontsize of the figure title
 
-    plt.rcParams["image.cmap"] = "cmo.haline"
+    plt.rcParams["image.cmap"] = "cmo.thermal"
     plt.rcParams["axes.xmargin"] = 0.05
     plt.rcParams["axes.ymargin"] = 0.1
     plt.rcParams["axes.titlelocation"] = "left"

code/modules/plotstyle1.py

@@ -0,0 +1,407 @@
+import cmocean as cmo
+import matplotlib.pyplot as plt
+import numpy as np
+from cycler import cycler
+from matplotlib.colors import ListedColormap
+
+
+def PlotStyle() -> None:
+    class style:
+
+        # lightcmap = cmocean.tools.lighten(cmocean.cm.haline, 0.8)
+
+        # units
+        cm = 1 / 2.54
+        mm = 1 / 25.4
+
+        # colors
+        black = "#111116"
+        white = "#e0e4f7"
+        gray = "#6c6e7d"
+        blue = "#89b4fa"
+        sapphire = "#74c7ec"
+        sky = "#89dceb"
+        teal = "#94e2d5"
+        green = "#a6e3a1"
+        yellow = "#f9d67f"
+        orange = "#faa472"
+        maroon = "#eb8486"
+        red = "#f37588"
+        purple = "#d89bf7"
+        pink = "#f59edb"
+        lavender = "#b4befe"
+        gblue1 = "#89b4fa"
+        gblue2 = "#89dceb"
+        gblue3 = "#a6e3a1"
+        g = "#76a0fa"
+
+        @classmethod
+        def lims(cls, track1, track2):
+            """Helper function to get frequency y axis limits from two
+            fundamental frequency tracks.
+
+            Args:
+                track1 (array): First track
+                track2 (array): Second track
+                start (int): Index for first value to be plotted
+                stop (int): Index for second value to be plotted
+                padding (int): Padding for the upper and lower limit
+
+            Returns:
+                lower (float): lower limit
+                upper (float): upper limit
+
+            """
+            allfunds_tmp = (
+                np.concatenate(
+                    [
+                        track1,
+                        track2,
+                    ]
+                )
+                .ravel()
+                .tolist()
+            )
+            lower = np.min(allfunds_tmp)
+            upper = np.max(allfunds_tmp)
+            return lower, upper
+
+        @classmethod
+        def circled_annotation(cls, text, axis, xpos, ypos, padding=0.25):
+            axis.text(
+                xpos,
+                ypos,
+                text,
+                ha="center",
+                va="center",
+                zorder=1000,
+                bbox=dict(
+                    boxstyle=f"circle, pad={padding}", fc="white", ec="black", lw=1
+                ),
+            )
+
+        @classmethod
+        def fade_cmap(cls, cmap):
+
+            my_cmap = cmap(np.arange(cmap.N))
+            my_cmap[:, -1] = np.linspace(0, 1, cmap.N)
+            my_cmap = ListedColormap(my_cmap)
+
+            return my_cmap
+
+        @classmethod
+        def hide_ax(cls, ax):
+            ax.xaxis.set_visible(False)
+            plt.setp(ax.spines.values(), visible=False)
+            ax.tick_params(left=False, labelleft=False)
+            ax.patch.set_visible(False)
+
+        @classmethod
+        def hide_xax(cls, ax):
+            ax.xaxis.set_visible(False)
+            ax.spines["bottom"].set_visible(False)
+
+        @classmethod
+        def hide_yax(cls, ax):
+            ax.yaxis.set_visible(False)
+            ax.spines["left"].set_visible(False)
+
+        @classmethod
+        def set_boxplot_color(cls, bp, color):
+            plt.setp(bp["boxes"], color=color)
+            plt.setp(bp["whiskers"], color=white)
+            plt.setp(bp["caps"], color=white)
+            plt.setp(bp["medians"], color=black)
+
+        @classmethod
+        def label_subplots(cls, labels, axes, fig):
+            for axis, label in zip(axes, labels):
+                X = axis.get_position().x0
+                Y = axis.get_position().y1
+                fig.text(X, Y, label, weight="bold")
+
+        @classmethod
+        def letter_subplots(
+            cls, axes=None, letters=None, xoffset=-0.1, yoffset=1.0, **kwargs
+        ):
+            """Add letters to the corners of subplots (panels). By default each axis is
+            given an uppercase bold letter label placed in the upper-left corner.
+            Args
+                axes : list of pyplot ax objects. default plt.gcf().axes.
+                letters : list of strings to use as labels, default ["A", "B", "C", ...]
+                xoffset, yoffset : positions of each label relative to plot frame
+                (default -0.1,1.0 = upper left margin). Can also be a list of
+                offsets, in which case it should be the same length as the number of
+                axes.
+                Other keyword arguments will be passed to annotate() when panel letters
+                are added.
+            Returns:
+                list of strings for each label added to the axes
+            Examples:
+                Defaults:
+                    >>> fig, axes = plt.subplots(1,3)
+                    >>> letter_subplots() # boldfaced A, B, C
+
+                Common labeling schemes inferred from the first letter:
+                    >>> fig, axes = plt.subplots(1,4)
+                    # panels labeled (a), (b), (c), (d)
+                    >>> letter_subplots(letters='(a)')
+                Fully custom lettering:
+                    >>> fig, axes = plt.subplots(2,1)
+                    >>> letter_subplots(axes, letters=['(a.1)', '(b.2)'], fontweight='normal')
+                Per-axis offsets:
+                    >>> fig, axes = plt.subplots(1,2)
+                    >>> letter_subplots(axes, xoffset=[-0.1, -0.15])
+
+                Matrix of axes:
+                    >>> fig, axes = plt.subplots(2,2, sharex=True, sharey=True)
+                    # fig.axes is a list when axes is a 2x2 matrix
+                    >>> letter_subplots(fig.axes)
+            """
+
+            # get axes:
+            if axes is None:
+                axes = plt.gcf().axes
+            # handle single axes:
+            try:
+                iter(axes)
+            except TypeError:
+                axes = [axes]
+
+            # set up letter defaults (and corresponding fontweight):
+            fontweight = "bold"
+            ulets = list("ABCDEFGHIJKLMNOPQRSTUVWXYZ"[: len(axes)])
+            llets = list("abcdefghijklmnopqrstuvwxyz"[: len(axes)])
+            if letters is None or letters == "A":
+                letters = ulets
+            elif letters == "(a)":
+                letters = ["({})".format(lett) for lett in llets]
+                fontweight = "normal"
+            elif letters == "(A)":
+                letters = ["({})".format(lett) for lett in ulets]
+                fontweight = "normal"
+            elif letters in ("lower", "lowercase", "a"):
+                letters = llets
+
+            # make sure there are x and y offsets for each ax in axes:
+            if isinstance(xoffset, (int, float)):
+                xoffset = [xoffset] * len(axes)
+            else:
+                assert len(xoffset) == len(axes)
+            if isinstance(yoffset, (int, float)):
+                yoffset = [yoffset] * len(axes)
+            else:
+                assert len(yoffset) == len(axes)
+
+            # defaults for annotate (kwargs is second so it can overwrite these defaults):
+            my_defaults = dict(
+                fontweight=fontweight,
+                fontsize="large",
+                ha="center",
+                va="center",
+                xycoords="axes fraction",
+                annotation_clip=False,
+            )
+            kwargs = dict(list(my_defaults.items()) + list(kwargs.items()))
+
+            list_txts = []
+            for ax, lbl, xoff, yoff in zip(axes, letters, xoffset, yoffset):
+                t = ax.annotate(lbl, xy=(xoff, yoff), **kwargs)
+                list_txts.append(t)
+            return list_txts
+
+        pass
+
+    # rcparams text setup
+    SMALL_SIZE = 12
+    MEDIUM_SIZE = 14
+    BIGGER_SIZE = 16
+    black = "#111116"
+    white = "#e0e4f7"
+    gray = "#6c6e7d"
+    dark_gray = "#2a2a32"
+
+    # rcparams
+    plt.rc("font", size=MEDIUM_SIZE)  # controls default text sizes
+    plt.rc("axes", titlesize=MEDIUM_SIZE)  # fontsize of the axes title
+    plt.rc("axes", labelsize=MEDIUM_SIZE)  # fontsize of the x and y labels
+    plt.rc("xtick", labelsize=SMALL_SIZE)  # fontsize of the tick labels
+    plt.rc("ytick", labelsize=SMALL_SIZE)  # fontsize of the tick labels
+    plt.rc("legend", fontsize=SMALL_SIZE)  # legend fontsize
+    plt.rc("figure", titlesize=BIGGER_SIZE)  # fontsize of the figure title
+
+    plt.rcParams["image.cmap"] = "cmo.haline"
+    plt.rcParams["axes.xmargin"] = 0.05
+    plt.rcParams["axes.ymargin"] = 0.1
+    plt.rcParams["axes.titlelocation"] = "left"
+    plt.rcParams["axes.titlesize"] = BIGGER_SIZE
+    # plt.rcParams["axes.titlepad"] = -10
+    plt.rcParams["legend.frameon"] = False
+    plt.rcParams["legend.loc"] = "best"
+    plt.rcParams["legend.borderpad"] = 0.4
+    plt.rcParams["legend.facecolor"] = black
+    plt.rcParams["legend.edgecolor"] = black
+    plt.rcParams["legend.framealpha"] = 0.7
+    plt.rcParams["legend.borderaxespad"] = 0.5
+    plt.rcParams["legend.fancybox"] = False
+
+    # # specify the custom font to use
+    # plt.rcParams["font.family"] = "sans-serif"
+    # plt.rcParams["font.sans-serif"] = "Helvetica Now Text"
+
+    # dark mode modifications
+    plt.rcParams["boxplot.flierprops.color"] = white
+    plt.rcParams["boxplot.flierprops.markeredgecolor"] = gray
+    plt.rcParams["boxplot.boxprops.color"] = gray
+    plt.rcParams["boxplot.whiskerprops.color"] = gray
+    plt.rcParams["boxplot.capprops.color"] = gray
+    plt.rcParams["boxplot.medianprops.color"] = black
+    plt.rcParams["text.color"] = white
+    plt.rcParams["axes.facecolor"] = black  # axes background color
+    plt.rcParams["axes.edgecolor"] = white  # axes edge color
+    # plt.rcParams["axes.grid"] = True    # display grid or not
+    # plt.rcParams["axes.grid.axis"] = "y"  # which axis the grid is applied to
+    plt.rcParams["axes.labelcolor"] = white
+    plt.rcParams["axes.axisbelow"] = True  # draw axis gridlines and ticks:
+    plt.rcParams["axes.spines.left"] = True  # display axis spines
+    plt.rcParams["axes.spines.bottom"] = True
+    plt.rcParams["axes.spines.top"] = False
+    plt.rcParams["axes.spines.right"] = False
+    plt.rcParams["axes.prop_cycle"] = cycler(
+        "color",
+        [
+            "#b4befe",
+            "#89b4fa",
+            "#74c7ec",
+            "#89dceb",
+            "#94e2d5",
+            "#a6e3a1",
+            "#f9e2af",
+            "#fab387",
+            "#eba0ac",
+            "#f38ba8",
+            "#cba6f7",
+            "#f5c2e7",
+        ],
+    )
+    plt.rcParams["xtick.color"] = white  # color of the ticks
+    plt.rcParams["ytick.color"] = white  # color of the ticks
+    plt.rcParams["grid.color"] = white  # grid color
+    plt.rcParams["figure.facecolor"] = black  # figure face color
+    plt.rcParams["figure.edgecolor"] = black  # figure edge color
+    plt.rcParams["savefig.facecolor"] = black  # figure face color when saving
+
+    return style
+
+
+if __name__ == "__main__":
+
+    s = PlotStyle()
+
+    import matplotlib.cbook as cbook
+    import matplotlib.cm as cm
+    import matplotlib.pyplot as plt
+    from matplotlib.patches import PathPatch
+    from matplotlib.path import Path
+
+    # Fixing random state for reproducibility
+    np.random.seed(19680801)
+
+    delta = 0.025
+    x = y = np.arange(-3.0, 3.0, delta)
+    X, Y = np.meshgrid(x, y)
+    Z1 = np.exp(-(X**2) - Y**2)
+    Z2 = np.exp(-((X - 1) ** 2) - (Y - 1) ** 2)
+    Z = (Z1 - Z2) * 2
+
+    fig1, ax = plt.subplots()
+    im = ax.imshow(
+        Z,
+        interpolation="bilinear",
+        cmap=cm.RdYlGn,
+        origin="lower",
+        extent=[-3, 3, -3, 3],
+        vmax=abs(Z).max(),
+        vmin=-abs(Z).max(),
+    )
+
+    plt.show()
+
+    fig, axs = plt.subplots(nrows=1, ncols=2, figsize=(9, 4))
+
+    # Fixing random state for reproducibility
+    np.random.seed(19680801)
+
+    # generate some random test data
+    all_data = [np.random.normal(0, std, 100) for std in range(6, 10)]
+
+    # plot violin plot
+    axs[0].violinplot(all_data, showmeans=False, showmedians=True)
+    axs[0].set_title("Violin plot")
+
+    # plot box plot
+    axs[1].boxplot(all_data)
+    axs[1].set_title("Box plot")
+
+    # adding horizontal grid lines
+    for ax in axs:
+        ax.yaxis.grid(True)
+        ax.set_xticks(
+            [y + 1 for y in range(len(all_data))], labels=["x1", "x2", "x3", "x4"]
+        )
+        ax.set_xlabel("Four separate samples")
+        ax.set_ylabel("Observed values")
+
+    plt.show()
+
+    # Fixing random state for reproducibility
+    np.random.seed(19680801)
+
+    # Compute pie slices
+    N = 20
+    theta = np.linspace(0.0, 2 * np.pi, N, endpoint=False)
+    radii = 10 * np.random.rand(N)
+    width = np.pi / 4 * np.random.rand(N)
+    colors = cmo.cm.haline(radii / 10.0)
+
+    ax = plt.subplot(projection="polar")
+    ax.bar(theta, radii, width=width, bottom=0.0, color=colors, alpha=0.5)
+
+    plt.show()
+
+    methods = [
+        None,
+        "none",
+        "nearest",
+        "bilinear",
+        "bicubic",
+        "spline16",
+        "spline36",
+        "hanning",
+        "hamming",
+        "hermite",
+        "kaiser",
+        "quadric",
+        "catrom",
+        "gaussian",
+        "bessel",
+        "mitchell",
+        "sinc",
+        "lanczos",
+    ]
+
+    # Fixing random state for reproducibility
+    np.random.seed(19680801)
+
+    grid = np.random.rand(4, 4)
+
+    fig, axs = plt.subplots(
+        nrows=3, ncols=6, figsize=(9, 6), subplot_kw={"xticks": [], "yticks": []}
+    )
+
+    for ax, interp_method in zip(axs.flat, methods):
+        ax.imshow(grid, interpolation=interp_method)
+        ax.set_title(str(interp_method))
+
+    plt.tight_layout()
+    plt.show()

code/plot_chirp_size.py

@@ -262,7 +262,7 @@ def main(datapath: str):
 
     stat = wilcoxon(chirps_winner, chirps_loser)
     print(stat)
-    winner_color = ps.gblue3
+    winner_color = ps.gblue2
     loser_color = ps.gblue1
 
     bplot1 = ax1.boxplot(chirps_winner, positions=[

code/plot_event_timeline.py

@@ -48,16 +48,16 @@ def main(datapath: str):
         fish1 = (bh.chirps[bh.chirps_ids == fish1_id] / 60) / 60
         fish2 = (bh.chirps[bh.chirps_ids == fish2_id] / 60) / 60
         fish1_color = ps.gblue1
-        fish2_color = ps.gblue3
+        fish2_color = ps.gblue2
 
         fig, ax = plt.subplots(5, 1, figsize=(
             21*ps.cm, 10*ps.cm), height_ratios=[0.5, 0.5, 0.5, 0.2, 6], sharex=True)
         # marker size
         s = 80
         ax[0].scatter(physical_contact, np.ones(
-            len(physical_contact)), color=ps.red, marker='|', s=s)
+            len(physical_contact)), color=ps.gray, marker='|', s=s)
         ax[1].scatter(chasing_onset, np.ones(len(chasing_onset)),
-                      color=ps.purple, marker='|', s=s)
+                      color=ps.gray, marker='|', s=s)
         ax[2].scatter(fish1, np.ones(len(fish1))-0.25,
                       color=fish1_color, marker='|', s=s)
         ax[2].scatter(fish2, np.zeros(len(fish2))+0.25,

code/plot_kdes.py

@@ -276,7 +276,7 @@ def main(dataroot):
             #     loser_physicals[-1], kde_time, kernel_width)
 
             ax[i].plot(kde_time, loser_offsets_conv /
-                       len(offsets), lw=2, zorder=100)
+                       len(offsets), lw=2, zorder=100, c=ps.gblue1)
 
             ax[i].fill_between(
                 kde_time,