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metadata
language:
  - en
task_categories:
  - robotics
  - reinforcement-learning
tags:
  - robotics
  - manipulation
  - imitation-learning
  - world-model
  - robot-learning
  - tabletop
pretty_name: World Model Robot Manipulation Dataset (Our-50)
size_categories:
  - n<1K

World Model Robot Manipulation Dataset

A dataset of real-robot tabletop manipulation trajectories collected for world model training and imitation learning research. The setup follows DROID Dataset. Each trajectory pairs multi-camera video, proprioceptive state/action sequences, natural language task descriptions, and dense reward annotations with pre-extracted visual latents.

Dataset Summary

Split Trajectories Success Rate Avg. Length
Train 250 44.8% 118 frames
Val 100 44.0% 106 frames
Total 350 44.6% 115 frames

Five tabletop manipulation tasks, 50 train / 20 val trajectories per task.

Tasks

Task ID Description Train SR Val SR
bag_our Pick up a bag of chips and place it on a green plate 54% 60%
marker_our Pick up a marker and place it in a cup/mug 36% 30%
pour_our Pick up a cup of beans and place them in a bowl 34% 30%
stack_our Pick up a bowl and stack it on top of another bowl 60% 60%
towel_our Pick up a towel and place it in a basket 40% 40%

Each task has multiple natural-language paraphrases (e.g. "put the marker in the cup", "put the marker in the mug", "pick up the marker and place it in the cup").

Data Structure

world_model_data_our_50/
├── annotations/
│   ├── train/   {0..249}.json
│   └── val/     {0..99}.json
├── annotation_rewards/
│   ├── train/   {0..249}.json       # same schema as annotations, includes reward fields
│   └── val/     {0..99}.json
├── latents/
│   ├── train/   {0..249}_sd3.npz
│   └── val/     {0..99}_sd3.npz
├── videos/
│   ├── train/   {0..249}.mp4
│   └── val/     {0..99}.mp4
├── norm_stats_recorded.json
└── norm_stats_relabel.json

Annotation JSON Schema

Each .json file contains one trajectory with the following fields:

Field Type Description
episode_id int Sequential trajectory index within the split
episode_id_orig str Original episode identifier (e.g. bag_our_003)
texts list[str] Natural language task descriptions
text_features float[768] Pre-computed text embedding
success int Binary success label (1 = task completed)
video_length int Number of frames in the trajectory (32–334)
video_path str Relative path to the .mp4 file
latent_path str Relative path to the latent .npz file
num_cameras int Always 3
states float[T][7] Raw proprioceptive state per frame
observation.state.cartesian_position float[T][6] End-effector Cartesian pose (x, y, z, rx, ry, rz)
observation.state.joint_position float[T][7] 7-DOF joint positions
observation.state.gripper_position float[T][1] Gripper opening
action.cartesian_position float[T][6] Cartesian position action
action.joint_position float[T][7] Joint position action
action.joint_velocity float[T][7] Joint velocity action
action.gripper_position float[T][1] Gripper action
reward_progress float[T] Dense progress reward
reward_success float[T] Success-shaped reward
reward_binary float[T] Binary reward signal

Video Format

  • Resolution: 960 × 192 (three 320 × 192 camera views (left, right, wrist) concatenated horizontally)
  • Codec: H.264
  • Frame rate: 5 fps
  • Length: 32–334 frames per trajectory

Visual Latents

Pre-extracted with Stable Diffusion 3 (SD3). Stored as float16 NumPy arrays.

latents.npz  →  key: "latents"
shape: (3, T, 60, 256)
        │  │   │    └─ channel dim
        │  │   └─ spatial tokens
        │  └─ frames
        └─ cameras

Normalization Statistics

norm_stats_recorded.json and norm_stats_relabel.json provide mean/std statistics for the state and actions modalities, suitable for normalizing inputs during training.

Robot Setup

  • Robot: Franka Emika Robot arm with parallel-jaw gripper (Robotiq Gripper)
  • Cameras: 3 fixed cameras providing left, right, and wrist views
  • Control frequency: 5 Hz (matches video frame rate)

Usage Example

import json
import numpy as np

# Load a trajectory
with open("annotations/train/0.json") as f:
    traj = json.load(f)

print(traj["texts"])          # ['pick up the bag of chips and place it on the green plate']
print(traj["success"])        # 1
print(traj["video_length"])   # e.g. 112

# Joint positions: shape (T, 7)
joint_pos = np.array(traj["observation.state.joint_position"])

# Actions: shape (T, 7)
actions = np.array(traj["action.joint_position"])

# Visual latents: shape (3, T, 60, 256)
lat = np.load(traj["latent_path"].replace("latents/", "latents/"))["latents"]

# Rewards: shape (T,)
rewards = np.array(traj["reward_progress"])