| import os |
| import numpy as np |
| import matplotlib.pyplot as plt |
| from tqdm import tqdm |
| from action_state.utils import ( |
| CO3DDataLoader, |
| get_camera_center, |
| get_view_direction, |
| get_sequence_geometry |
| ) |
|
|
| |
| ROOT_PATH = "/run/determined/NAS1/public/lixinyuan/interleaved-co3d" |
| CATEGORY = "hairdryer" |
| SEQUENCE_NAME = "400_51395_100959" |
| OUTPUT_DIR = "./debug/traj/task1_v2" |
|
|
| HIGHLIGHT_FRAMES = [5, 111, 92, 143, 172, 141, 129, 119] |
|
|
|
|
| def plot_sequence_trajectory(loader, sequence_name, output_path, highlight_frames=None, verbose=True): |
| """ |
| 绘制单个序列的轨迹图 |
| |
| Args: |
| loader: CO3DDataLoader 实例 |
| sequence_name: 序列名称 |
| output_path: 输出文件路径 |
| highlight_frames: 需要高亮的帧ID列表 |
| verbose: 是否显示详细信息 |
| """ |
| if verbose: |
| print(f"\n{'='*60}") |
| print(f"Processing sequence: {sequence_name}") |
| print(f"{'='*60}") |
| |
| frame_ids = sorted(loader.get_frames(sequence_name)) |
| seq_data = loader.seq_data[sequence_name] |
| |
| |
| mean_center, basis, aligned_seq_data = get_sequence_geometry( |
| seq_data, align_to_standard=True |
| ) |
| |
| if verbose: |
| print(f"Scene Alignment Info:") |
| print(f" Original CO3D ground normal: [-0.0396, -0.8306, -0.5554]") |
| print(f" Aligned to standard Y-up: [0, 1, 0]") |
| print(f" Object center: {mean_center}") |
| print(f" Total frames: {len(frame_ids)}") |
| |
| |
| camera_centers = [] |
| view_dirs = [] |
| |
| for fid in frame_ids: |
| info = aligned_seq_data[fid] |
| C = get_camera_center(info['R'], info['T']) |
| V = get_view_direction(info['R']) |
| camera_centers.append(C) |
| view_dirs.append(V) |
|
|
| camera_centers = np.array(camera_centers) |
| view_dirs = np.array(view_dirs) |
| |
| |
| x_coords = camera_centers[:, 0] - mean_center[0] |
| z_coords = camera_centers[:, 2] - mean_center[2] |
| y_coords = camera_centers[:, 1] - mean_center[1] |
| |
| |
| view_x = view_dirs[:, 0] |
| view_z = view_dirs[:, 2] |
| |
| view_ground_norm = np.sqrt(view_x**2 + view_z**2) |
| view_ground_norm[view_ground_norm < 1e-6] = 1.0 |
| view_x_normalized = view_x / view_ground_norm |
| view_z_normalized = view_z / view_ground_norm |
| |
| |
| fig, ax = plt.subplots(1, 1, figsize=(12, 10)) |
| |
| |
| ax.plot(x_coords, z_coords, c='lightgray', alpha=0.5, |
| linestyle='--', linewidth=2, label='Camera Trajectory') |
| |
| sc = ax.scatter(x_coords, z_coords, c=frame_ids, cmap='viridis', |
| s=50, zorder=5, alpha=0.7, edgecolors='white', linewidths=0.5) |
| cbar = plt.colorbar(sc, ax=ax, label='Frame ID') |
| |
| ax.scatter(0, 0, c='black', marker='X', s=300, linewidths=3, |
| label='Object Center', zorder=15, edgecolors='yellow') |
| |
| |
| highlight_indices = [] |
| if highlight_frames: |
| for i, fid in enumerate(frame_ids): |
| if fid in highlight_frames: |
| highlight_indices.append(i) |
| |
| ax.scatter(x_coords[i], z_coords[i], c='red', s=200, zorder=12, |
| edgecolors='black', linewidths=2.5, marker='o') |
| |
| arrow_scale = max(np.std(x_coords), np.std(z_coords)) * 0.3 |
| ax.arrow(x_coords[i], z_coords[i], |
| view_x_normalized[i] * arrow_scale, |
| view_z_normalized[i] * arrow_scale, |
| head_width=arrow_scale*0.15, |
| head_length=arrow_scale*0.2, |
| fc='red', ec='darkred', zorder=11, linewidth=2.5, alpha=0.8) |
| |
| ax.text(x_coords[i], z_coords[i] - arrow_scale*0.5, |
| str(fid), fontsize=16, color='red', fontweight='bold', |
| ha='center', va='top', |
| bbox=dict(boxstyle='round,pad=0.4', |
| facecolor='yellow', edgecolor='red', |
| alpha=0.9, linewidth=2)) |
| |
| ax.plot([0, x_coords[i]], [0, z_coords[i]], |
| 'k:', alpha=0.4, linewidth=1.5, zorder=1) |
| |
| |
| if len(highlight_indices) > 1: |
| ref_idx = highlight_indices[0] |
| ref_angle = np.arctan2(z_coords[ref_idx], x_coords[ref_idx]) |
| |
| angle_info = f"Reference Frame: {frame_ids[ref_idx]} (angle=0°)\n" |
| for idx in highlight_indices[1:]: |
| curr_angle = np.arctan2(z_coords[idx], x_coords[idx]) |
| diff_angle = np.degrees(curr_angle - ref_angle) |
| diff_angle = (diff_angle + 180) % 360 - 180 |
| direction = "CCW" if diff_angle > 0 else "CW" |
| angle_info += f"Frame {frame_ids[idx]}: {abs(diff_angle):.1f}° {direction}\n" |
| |
| ax.text(0.02, 0.98, angle_info, transform=ax.transAxes, |
| fontsize=11, verticalalignment='top', |
| bbox=dict(boxstyle='round', facecolor='wheat', alpha=0.8), |
| family='monospace') |
| |
| ax.set_title(f"Top-Down View (Ground Plane Projection)\n" |
| f"Aligned to Standard Coordinate System (Y-up)", |
| fontsize=14, fontweight='bold') |
| ax.set_xlabel("X Coordinate (Horizontal, relative to object)", fontsize=12) |
| ax.set_ylabel("Z Coordinate (Horizontal, relative to object)", fontsize=12) |
| ax.axis('equal') |
| ax.grid(True, alpha=0.3, linestyle='--', linewidth=0.5) |
| ax.legend(fontsize=11, loc='upper right') |
| ax.axhline(y=0, color='k', linewidth=0.5, alpha=0.3) |
| ax.axvline(x=0, color='k', linewidth=0.5, alpha=0.3) |
| |
| plt.suptitle(f"CO3D Scene Aligned to Standard Coordinate System\n" |
| f"Sequence: {CATEGORY}/{sequence_name}\n" |
| f"Ground Normal: CO3D [-0.0396,-0.8306,-0.5554] → Standard [0,1,0]", |
| fontsize=15, fontweight='bold') |
| |
| plt.tight_layout() |
| plt.savefig(output_path, dpi=200, bbox_inches='tight') |
| plt.close(fig) |
| |
| if verbose: |
| print(f"✓ Plot saved to {output_path}") |
| print(f" Camera height (Y) range: [{y_coords.min():.3f}, {y_coords.max():.3f}]") |
| print(f" Ground projection range:") |
| print(f" X ∈ [{x_coords.min():.3f}, {x_coords.max():.3f}]") |
| print(f" Z ∈ [{z_coords.min():.3f}, {z_coords.max():.3f}]") |
|
|
|
|
| def main(): |
| print(f"Loading CO3D data from: {ROOT_PATH}") |
| print(f"Category: {CATEGORY}") |
| |
| loader = CO3DDataLoader(ROOT_PATH, CATEGORY) |
| |
| |
| os.makedirs(OUTPUT_DIR, exist_ok=True) |
| print(f"Output directory: {OUTPUT_DIR}") |
| |
| if SEQUENCE_NAME is None or SEQUENCE_NAME == "": |
| |
| sequences = loader.get_sequences() |
| print(f"\n{'='*60}") |
| print(f"Processing ALL sequences in category '{CATEGORY}'") |
| print(f"Total sequences: {len(sequences)}") |
| print(f"{'='*60}\n") |
| |
| success_count = 0 |
| error_count = 0 |
| |
| |
| for seq_name in tqdm(sequences, desc="Processing sequences", unit="seq"): |
| output_path = os.path.join(OUTPUT_DIR, f"{seq_name}_traj.png") |
| |
| try: |
| plot_sequence_trajectory( |
| loader, |
| seq_name, |
| output_path, |
| highlight_frames=HIGHLIGHT_FRAMES, |
| verbose=False |
| ) |
| success_count += 1 |
| except Exception as e: |
| tqdm.write(f"✗ Error processing {seq_name}: {e}") |
| error_count += 1 |
| continue |
| |
| print(f"\n{'='*60}") |
| print(f"✓ Processing completed!") |
| print(f" Success: {success_count}/{len(sequences)}") |
| if error_count > 0: |
| print(f" Failed: {error_count}/{len(sequences)}") |
| print(f" Output directory: {OUTPUT_DIR}") |
| print(f"{'='*60}") |
| |
| else: |
| |
| if SEQUENCE_NAME not in loader.get_sequences(): |
| print(f"Error: Sequence {SEQUENCE_NAME} not found in category {CATEGORY}.") |
| print(f"Available sequences: {loader.get_sequences()}") |
| return |
| |
| output_path = os.path.join(OUTPUT_DIR, f"{SEQUENCE_NAME}_traj.png") |
| plot_sequence_trajectory( |
| loader, |
| SEQUENCE_NAME, |
| output_path, |
| highlight_frames=HIGHLIGHT_FRAMES, |
| verbose=True |
| ) |
|
|
|
|
| if __name__ == "__main__": |
| main() |
|
|
