fixed plots

tools/plot_scripts/ae_elbow_lenet.py

@@ -12,7 +12,7 @@ import numpy as np
 import polars as pl
 
 # CHANGE THIS IMPORT IF YOUR LOADER MODULE IS NAMED DIFFERENTLY
-from plot_scripts.load_results import load_pretraining_results_dataframe
+from load_results import load_pretraining_results_dataframe
 
 # ----------------------------
 # Config
@@ -78,8 +78,8 @@ def build_arch_curves_from_df(
             "overall": (dims, means, stds),
         } }
     """
-    if "split" not in df.columns:
-        raise ValueError("Expected 'split' column in AE dataframe.")
+    # if "split" not in df.columns:
+    #     raise ValueError("Expected 'split' column in AE dataframe.")
     if "scores" not in df.columns:
         raise ValueError("Expected 'scores' column in AE dataframe.")
     if "network" not in df.columns or "latent_dim" not in df.columns:
@@ -88,7 +88,7 @@ def build_arch_curves_from_df(
         raise ValueError(f"Expected '{label_field}' column in AE dataframe.")
 
     # Keep only test split
-    df = df.filter(pl.col("split") == "test")
+    # df = df.filter(pl.col("split") == "test")
 
     groups: dict[tuple[str, int], dict[str, list[float]]] = {}
 
@@ -201,7 +201,7 @@ def plot_multi_loss_curve(arch_results, title, output_path, colors=None):
 
     plt.xlabel("Latent Dimensionality")
     plt.ylabel("Test Loss")
-    plt.title(title)
+    # plt.title(title)
     plt.legend()
     plt.grid(True, alpha=0.3)
     plt.xticks(all_dims)

tools/plot_scripts/data_anomalies_timeline.py

@@ -171,28 +171,28 @@ def plot_combined_timeline(
             range(num_bins), near_sensor_binned, color=color, linestyle="--", alpha=0.6
         )
 
-        # Add vertical lines for manually labeled frames if available
-        if all_paths[i].with_suffix(".npy").name in manually_labeled_anomaly_frames:
-            begin_frame, end_frame = manually_labeled_anomaly_frames[
-                all_paths[i].with_suffix(".npy").name
-            ]
-            # Convert frame numbers to normalized timeline positions
-            begin_pos = (begin_frame / exp_len) * (num_bins - 1)
-            end_pos = (end_frame / exp_len) * (num_bins - 1)
+        # # Add vertical lines for manually labeled frames if available
+        # if all_paths[i].with_suffix(".npy").name in manually_labeled_anomaly_frames:
+        #     begin_frame, end_frame = manually_labeled_anomaly_frames[
+        #         all_paths[i].with_suffix(".npy").name
+        #     ]
+        #     # Convert frame numbers to normalized timeline positions
+        #     begin_pos = (begin_frame / exp_len) * (num_bins - 1)
+        #     end_pos = (end_frame / exp_len) * (num_bins - 1)
 
-            # Add vertical lines with matching color and loose dotting
-            ax1.axvline(
-                x=begin_pos,
-                color=color,
-                linestyle=":",
-                alpha=0.6,
-            )
-            ax1.axvline(
-                x=end_pos,
-                color=color,
-                linestyle=":",
-                alpha=0.6,
-            )
+        #     # Add vertical lines with matching color and loose dotting
+        #     ax1.axvline(
+        #         x=begin_pos,
+        #         color=color,
+        #         linestyle=":",
+        #         alpha=0.6,
+        #     )
+        #     ax1.axvline(
+        #         x=end_pos,
+        #         color=color,
+        #         linestyle=":",
+        #         alpha=0.6,
+        #     )
 
     # Customize axes
     ax1.set_xlabel("Normalized Timeline")
@@ -202,7 +202,7 @@ def plot_combined_timeline(
     ax1.set_ylabel("Missing Points (%)")
     ax2.set_ylabel("Points with <0.5m Range (%)")
 
-    plt.title(title)
+    # plt.title(title)
 
     # Create legends without fixed positions
     # First get all lines and labels for experiments
@@ -221,7 +221,8 @@ def plot_combined_timeline(
     )
 
     # Create single legend in top right corner with consistent margins
-    fig.legend(all_handles, all_labels, loc="upper right", borderaxespad=4.8)
+    # fig.legend(all_handles, all_labels, loc="upper right", borderaxespad=2.8)
+    fig.legend(all_handles, all_labels, bbox_to_anchor=(0.95, 0.99))
 
     plt.grid(True, alpha=0.3)
 

tools/plot_scripts/data_count_lidar_frames.py

@@ -122,8 +122,8 @@ def plot_data_points_pie(normal_experiment_frames, anomaly_experiment_frames):
 
     # prepare data for pie chart
     labels = [
-        "Normal Lidar Frames\nNon-Degraded Pointclouds",
-        "Anomalous Lidar Frames\nDegraded Pointclouds",
+        "Normal Lidar Frames\nNon-Degraded Point Clouds",
+        "Anomalous Lidar Frames\nDegraded Point Clouds",
     ]
     sizes = [total_normal_frames, total_anomaly_frames]
     explode = (0.1, 0)  # explode the normal slice
@@ -150,9 +150,9 @@ def plot_data_points_pie(normal_experiment_frames, anomaly_experiment_frames):
         va="center",
         color="black",
     )
-    plt.title(
-        "Distribution of Normal and Anomalous\nPointclouds in all Experiments (Lidar Frames)"
-    )
+    # plt.title(
+    #     "Distribution of Normal and Anomalous\nPointclouds in all Experiments (Lidar Frames)"
+    # )
     plt.tight_layout()
 
     # save the plot

tools/plot_scripts/data_missing_points.py

@@ -5,7 +5,6 @@ from pathlib import Path
 
 import matplotlib.pyplot as plt
 import numpy as np
-from pointcloudset import Dataset
 
 # define data path containing the bag files
 all_data_path = Path("/home/fedex/mt/data/subter")
@@ -82,7 +81,7 @@ def plot_data_points(normal_experiment_paths, anomaly_experiment_paths, title):
     plt.figure(figsize=(10, 5))
     plt.hist(missing_points_normal, bins=100, alpha=0.5, label="Normal Experiments")
     plt.hist(missing_points_anomaly, bins=100, alpha=0.5, label="Anomaly Experiments")
-    plt.title(title)
+    # plt.title(title)
     plt.xlabel("Number of Missing Points")
     plt.ylabel("Number of Pointclouds")
     plt.legend()
@@ -109,7 +108,7 @@ def plot_data_points(normal_experiment_paths, anomaly_experiment_paths, title):
         label="Anomaly Experiments",
         orientation="horizontal",
     )
-    plt.title(title)
+    # plt.title(title)
     plt.xlabel("Number of Pointclouds")
     plt.ylabel("Number of Missing Points")
     plt.legend()
@@ -142,7 +141,7 @@ def plot_data_points(normal_experiment_paths, anomaly_experiment_paths, title):
         label="Anomaly Experiments",
         density=True,
     )
-    plt.title(title)
+    # plt.title(title)
     plt.xlabel("Number of Missing Points")
     plt.ylabel("Density")
     plt.legend()
@@ -169,7 +168,7 @@ def plot_data_points(normal_experiment_paths, anomaly_experiment_paths, title):
         label="Anomaly Experiments (With Artifical Smoke)",
         density=True,
     )
-    plt.title(title)
+    # plt.title(title)
     plt.xlabel("Percentage of Missing Lidar Measurements")
     plt.ylabel("Density")
     # display the x axis as percentages
@@ -210,7 +209,7 @@ def plot_data_points(normal_experiment_paths, anomaly_experiment_paths, title):
         alpha=0.5,
         label="Anomaly Experiments",
     )
-    plt.title(title)
+    # plt.title(title)
     plt.xlabel("Number of Missing Points")
     plt.ylabel("Normalized Density")
     plt.legend()

tools/plot_scripts/data_particles_near_sensor.py

@@ -5,7 +5,6 @@ from pathlib import Path
 
 import matplotlib.pyplot as plt
 import numpy as np
-from pointcloudset import Dataset
 
 # define data path containing the bag files
 all_data_path = Path("/home/fedex/mt/data/subter")
@@ -164,7 +163,7 @@ def plot_data_points(normal_experiment_paths, anomaly_experiment_paths, title):
         plt.gca().set_yticklabels(
             ["{:.0f}%".format(y * 100) for y in plt.gca().get_yticks()]
         )
-        plt.title("Particles Closer than 0.5m to the Sensor")
+        # plt.title("Particles Closer than 0.5m to the Sensor")
         plt.ylabel("Percentage of measurements closer than 0.5m")
         plt.tight_layout()
         plt.savefig(output_datetime_path / f"particles_near_sensor_boxplot_{rt}.png")
@@ -186,7 +185,7 @@ def plot_data_points(normal_experiment_paths, anomaly_experiment_paths, title):
         plt.gca().set_yticklabels(
             ["{:.0f}%".format(y * 100) for y in plt.gca().get_yticks()]
         )
-        plt.title("Particles Closer than 0.5m to the Sensor")
+        # plt.title("Particles Closer than 0.5m to the Sensor")
         plt.ylabel("Percentage of measurements closer than 0.5m")
         plt.ylim(0, 0.05)
         plt.tight_layout()

tools/plot_scripts/data_spherical_projection.py

@@ -112,18 +112,27 @@ cmap = get_colormap_with_special_missing_color(
     args.colormap, args.missing_data_color, args.reverse_colormap
 )
 
-# --- Create a figure with 2 vertical subplots ---
+# --- Create a figure with 2 vertical subplots and move titles to the left ---
 fig, (ax1, ax2) = plt.subplots(nrows=2, ncols=1, figsize=(10, 5))
-for ax, frame, title in zip(
+# leave extra left margin for the left-side labels
+fig.subplots_adjust(left=0.14, hspace=0.05)
+
+for ax, frame, label in zip(
     (ax1, ax2),
     (frame1, frame2),
-    (
-        "Projection of Lidar Frame without Degradation",
-        "Projection of Lidar Frame with Degradation (Artifical Smoke)",
-    ),
+    ("(a)", "(b)"),
 ):
     im = ax.imshow(frame, cmap=cmap, aspect="auto", vmin=global_vmin, vmax=global_vmax)
-    ax.set_title(title)
+    # place the "title" to the left, vertically centered relative to the axes
+    ax.text(
+        -0.02,  # negative x places text left of the axes (in axes coordinates)
+        0.5,
+        label,
+        transform=ax.transAxes,
+        va="center",
+        ha="right",
+        fontsize=12,
+    )
     ax.axis("off")
 
 # Adjust layout to fit margins for a paper

tools/plot_scripts/results_inference_timelines_exp_compare.py

@@ -260,11 +260,11 @@ def baseline_transform(clean: np.ndarray, other: np.ndarray, mode: str):
 
 
 def pick_method_series(gdf: pl.DataFrame, label: str) -> Optional[np.ndarray]:
-    if label == "DeepSAD (LeNet)":
+    if label == "DeepSAD LeNet":
         sel = gdf.filter(
             (pl.col("network") == "subter_LeNet") & (pl.col("model") == "deepsad")
         )
-    elif label == "DeepSAD (efficient)":
+    elif label == "DeepSAD Efficient":
         sel = gdf.filter(
             (pl.col("network") == "subter_efficient") & (pl.col("model") == "deepsad")
         )
@@ -311,8 +311,8 @@ def compare_two_experiments_progress(
     include_stats: bool = True,
 ):
     methods = [
-        "DeepSAD (LeNet)",
-        "DeepSAD (efficient)",
+        "DeepSAD LeNet",
+        "DeepSAD Efficient",
         "OCSVM",
         "Isolation Forest",
     ]
@@ -392,8 +392,8 @@ def compare_two_experiments_progress(
     axes = axes.ravel()
 
     method_to_axidx = {
-        "DeepSAD (LeNet)": 0,
-        "DeepSAD (efficient)": 1,
+        "DeepSAD LeNet": 0,
+        "DeepSAD Efficient": 1,
         "OCSVM": 2,
         "Isolation Forest": 3,
     }
@@ -404,6 +404,8 @@ def compare_two_experiments_progress(
     if not stats_available:
         print("[WARN] One or both stats missing. Subplots will include methods only.")
 
+    letters = ["a", "b", "c", "d"]
+
     for label, axidx in method_to_axidx.items():
         ax = axes[axidx]
         yc = curves_clean.get(label)
@@ -412,7 +414,7 @@ def compare_two_experiments_progress(
             ax.text(
                 0.5, 0.5, "No data", ha="center", va="center", transform=ax.transAxes
             )
-            ax.set_title(label)
+            ax.set_title(f"({letters[axidx]}) {label}")
             ax.grid(True, alpha=0.3)
             continue
 
@@ -435,6 +437,7 @@ def compare_two_experiments_progress(
         )
         ax.set_ylabel(y_label)
         ax.set_title(label)
+        ax.set_title(f"({letters[axidx]}) {label}")
         ax.grid(True, alpha=0.3)
 
         # Right axis #1 (closest to plot): Missing points (%)
@@ -550,11 +553,11 @@ def compare_two_experiments_progress(
     for ax in axes:
         ax.set_xlabel("Progress through experiment (%)")
 
-    fig.suptitle(
-        f"AD Method vs Stats Inference — progress-normalized\n"
-        f"Transform: z-score normalized to non-degraded experiment | EMA(α={EMA_ALPHA_METHODS})",
-        fontsize=14,
-    )
+    # fig.suptitle(
+    #     f"AD Method vs Stats Inference — progress-normalized\n"
+    #     f"Transform: z-score normalized to non-degraded experiment | EMA(α={EMA_ALPHA_METHODS})",
+    #     fontsize=14,
+    # )
     fig.tight_layout(rect=[0, 0, 1, 0.99])
 
     out_name = (

tools/plot_scripts/results_latent_space_comparisons.py

@@ -161,7 +161,7 @@ def _ensure_dim_axes(fig_title: str):
     fig, axes = plt.subplots(
         nrows=4, ncols=2, figsize=(12, 16), constrained_layout=True
     )
-    fig.suptitle(fig_title, fontsize=14)
+    # fig.suptitle(fig_title, fontsize=14)
     axes = axes.ravel()
     return fig, axes
 
@@ -213,11 +213,13 @@ def plot_grid_from_df(
     legend_labels = []
     have_legend = False
 
+    letters = ["a", "b", "c", "d", "e", "f", "g", "h"]
+
     for i, dim in enumerate(LATENT_DIMS):
         if i >= 7:
             break  # last slot reserved for legend
         ax = axes[i]
-        ax.set_title(f"Latent Dim. = {dim}")
+        ax.set_title(f"({letters[i]}) Latent Dim. = {dim}")
         ax.grid(True, alpha=0.3)
 
         if kind == "roc":

tools/plot_scripts/results_semi_labels_comparison.py

@@ -260,9 +260,9 @@ def make_figures_for_dim(
     fig_roc, axes = plt.subplots(
         nrows=2, ncols=1, figsize=(7, 10), constrained_layout=True
     )
-    fig_roc.suptitle(
-        f"ROC — {EVALS_LABELS[eval_type]} — Latent Dim.={latent_dim}", fontsize=14
-    )
+    # fig_roc.suptitle(
+    #     f"ROC — {EVALS_LABELS[eval_type]} — Latent Dim.={latent_dim}", fontsize=14
+    # )
 
     _plot_panel(
         axes[0],
@@ -272,7 +272,7 @@ def make_figures_for_dim(
         latent_dim=latent_dim,
         kind="roc",
     )
-    axes[0].set_title("DeepSAD (LeNet) + Baselines")
+    axes[0].set_title("(a) DeepSAD (LeNet) + Baselines")
 
     _plot_panel(
         axes[1],
@@ -282,7 +282,7 @@ def make_figures_for_dim(
         latent_dim=latent_dim,
         kind="roc",
     )
-    axes[1].set_title("DeepSAD (Efficient) + Baselines")
+    axes[1].set_title("(b) DeepSAD (Efficient) + Baselines")
 
     out_roc = out_dir / f"roc_{latent_dim}_{eval_type}.png"
     fig_roc.savefig(out_roc, dpi=150, bbox_inches="tight")
@@ -292,9 +292,9 @@ def make_figures_for_dim(
     fig_prc, axes = plt.subplots(
         nrows=2, ncols=1, figsize=(7, 10), constrained_layout=True
     )
-    fig_prc.suptitle(
-        f"PRC — {EVALS_LABELS[eval_type]} — Latent Dim.={latent_dim}", fontsize=14
-    )
+    # fig_prc.suptitle(
+    #     f"PRC — {EVALS_LABELS[eval_type]} — Latent Dim.={latent_dim}", fontsize=14
+    # )
 
     _plot_panel(
         axes[0],
@@ -304,7 +304,7 @@ def make_figures_for_dim(
         latent_dim=latent_dim,
         kind="prc",
     )
-    axes[0].set_title("DeepSAD (LeNet) + Baselines")
+    axes[0].set_title("(a)")
 
     _plot_panel(
         axes[1],
@@ -314,7 +314,7 @@ def make_figures_for_dim(
         latent_dim=latent_dim,
         kind="prc",
     )
-    axes[1].set_title("DeepSAD (Efficient) + Baselines")
+    axes[1].set_title("(b)")
 
     out_prc = out_dir / f"prc_{latent_dim}_{eval_type}.png"
     fig_prc.savefig(out_prc, dpi=150, bbox_inches="tight")