---
annotations_creators:
  - expert-generated
  - machine-generated
language:
  - en
license: cc-by-nc-sa-4.0
pretty_name: SceneFun3D
size_categories:
  - n<1K
splits:
  - train
  - val
  - test
task_categories:
  - object-detection
tags:
  - fiftyone
  - 3d
  - point-cloud
  - fo3d
  - group
  - video
  - rgbd
  - depth
  - affordance
  - functionality
  - indoor-scenes
  - robotics
dataset_summary: >
  SceneFun3D is a 3D scene-understanding dataset of high-resolution laser-scan
  point clouds of indoor environments densely annotated with fine-grained
  functional interactive elements (handles, knobs, buttons, switches, ...), their
  affordances, motion parameters, and natural-language task descriptions. This is
  the FiftyOne version: a grouped multimodal dataset where each scene is a group
  containing the scene's FO3D laser-scan point cloud (with 3D functional elements)
  plus one video slice per iPad recording of the scene. Video frames carry
  per-frame depth, camera poses, intrinsics, and the functional elements projected
  into the frames as 2D boxes + keypoints. This build samples 10 scenes from each
  of the train/val/test splits (each sample tagged with its split).
---

# Dataset Card for SceneFun3D

![image/png](scenefun3d.gif)

SceneFun3D is a 3D scene-understanding dataset of high-resolution Faro laser-scan point clouds of indoor environments, densely annotated with fine-grained
**functional interactive elements** (handles, knobs, buttons, switches, ...), their **affordances**, **motion** parameters, and free-form **task descriptions**.
Each scene is also captured by several iPad video sequences with RGB, depth, camera poses, and intrinsics.

This is the FiftyOne version of the dataset: a **grouped multimodal** dataset where each **scene** is a group containing the scene's FO3D laser-scan point cloud
(with 3D functional elements) plus one video slice per iPad recording (`ipad_1`, `ipad_2`, ...). The video frames carry per-frame depth (as `Heatmap` labels),
camera poses, and intrinsics, and the 3D functional elements are projected into the frames as 2D detections + keypoints, linked back to the 3D boxes via
`fo.Instance`.

This dataset was created with [FiftyOne](https://github.com/voxel51/fiftyone) and can be loaded and visualized in the FiftyOne App (3D viewer for the point cloud,
video player for the iPad sequences).

## Installation

```bash
pip install -U fiftyone
```

## Usage

Build the dataset (downloads visit + video assets on demand, then parses them):

```bash
import fiftyone as fo
from fiftyone.utils.huggingface import load_from_hub
from huggingface_hub import snapshot_download


# Download the dataset snapshot to the current working directory

snapshot_download(
    repo_id="Voxel51/SceneFun3D", 
    local_dir=".", 
    repo_type="dataset"
    )

# Load dataset from current directory using FiftyOne's native format
dataset = fo.Dataset.from_dir(
    dataset_dir=".",  # Current directory contains the dataset files
    dataset_type=fo.types.FiftyOneDataset,  # Specify FiftyOne dataset format
    name="SceneFun3D"  # Assign a name to the dataset for identification
)

# Launch the App
session = fo.launch_app(dataset)

```

## Dataset Details

### Dataset Description

<!-- Provide a longer summary of what this dataset is. -->

SceneFun3D targets *fine-grained functionality and affordance understanding* in 3D scenes: beyond recognizing objects, it localizes the small interactive parts a
person actually manipulates (a drawer handle, a light switch, a stove knob) and describes how to interact with them. The full dataset (per the paper) provides
**more than 14.8k (14,867) functional interactive element annotations across 710 high-resolution real-world indoor scenes**, with **9 Gibsonian-inspired affordance
categories**, **motion parameters for 14,279 elements** (8,325 translational, 6,542 rotational), and **natural-language task descriptions for 10,913 elements**
(17,133 including automated rephrasings). Each scene is a combined, 5mm-voxel-downsampled Faro laser scan (several million points); functional elements
are annotated as point-index masks on that scan.

In this FiftyOne build, every scene becomes one FO3D point cloud, each functional element becomes a 3D `Detection` (axis-aligned box from the masked points) carrying
its affordance and motion, and each scene's iPad recordings are video slices with the elements projected into the frames (see Dataset Structure).

- **Curated by:** Alexandros Delitzas, Ayca Takmaz, Federico Tombari, Robert
  Sumner, Marc Pollefeys, and Francis Engelmann (ETH Zurich, Google, TU Munich,
  Microsoft). Built on top of ARKitScenes.
  
- **Funded by:** A Career Seed Award from the ETH Zurich Foundation and an
  Innosuisse grant (48727.1 IP-ICT); AD supported by a HELLENiQ ENERGY scholarship.

- **Shared by:** SceneFun3D authors (ETH Zurich CVG release mirror).

- **Language(s):** English (task descriptions).

- **License:** Non-commercial research use, inherited from ARKitScenes
  (CC BY-NC-SA 4.0).

### Dataset Sources

<!-- Provide the basic links for the dataset. -->

- **Repository:** https://github.com/SceneFun3D/scenefun3d
  
- **Paper:** Delitzas et al. "SceneFun3D: Fine-Grained Functionality and
  Affordance Understanding in 3D Scenes." CVPR 2024 (Oral).

- **Demo:** https://scenefun3d.github.io

## Uses

### Direct Use

- Functional interactive element detection / segmentation in 3D point clouds.

- Affordance grounding (predicting the affordance class of interactive parts).

- Task-driven affordance grounding: localizing the 3D element that satisfies a
  natural-language instruction ("open the drawer next to the sink").

- Motion estimation for articulated/interactive parts (axis, direction, type).

- Robotics and embodied-AI research on manipulation target selection.


## Dataset Structure

<!-- This section provides a description of the dataset fields and structure. -->

This is a **grouped dataset** (`media_type = "group"`) where the group is one
**scene** (`visit_id`). Each group has:

- `laser_scan` (`3d`/FO3D) - the scene's Faro point cloud (RGB-shaded) carrying the
  3D `functional_elements`, `objects_3d`, and `tasks` (one per scene).

- `ipad_1`, `ipad_2`, ... (`video`) - one slice per iPad recording of the scene
  (high-res RGB, 1920x1440, ~10 FPS, re-encoded to H.264 MP4), with per-frame
  depth, pose, intrinsics, and the 3D elements/objects projected into the frame.
  Scenes have ~2-3 recordings; positional slices are populated up to that count
  (a 2-recording scene leaves `ipad_3` empty).

The default slice is `ipad_1`. This build samples **10 scenes from each of the
train / val / test splits** (30 scenes), and **every sample is tagged with its
split** (`train` / `val` / `test`). Image/video/scene `metadata` is computed for
all slices.

Note: the **test split's functional annotations are withheld** by the benchmark, so
test-split groups have the point cloud + video slices (and ARKit `objects_3d` where
available) but no `functional_elements` / `tasks` / projected functional labels.

### Sample fields (by slice)

Shared:

| Field | FiftyOne type | Description |
|-------|---------------|-------------|
| `filepath` | `StringField` | `.mp4` video (ipad_N) or `.fo3d` scene (laser_scan). |
| `group` | `Group` | Group membership + slice name. |
| `visit_id` | `StringField` | 6-digit scene identifier (verbatim). |
| `tags` | `ListField(StringField)` | Source split of the sample (`train` / `val` / `test`). |
| `metadata` | `SceneMetadata` / `VideoMetadata` | Computed media metadata (size, and frame count / dimensions for videos). |

`laser_scan` slice:

| Field | FiftyOne type | Description |
|-------|---------------|-------------|
| `functional_elements` | `Detections` | 3D functional interactive elements (one `Detection` per annotation), each linked to its 2D projections via `fo.Instance`. |
| `objects_3d` | `Detections` | ARKit room-level object boxes (e.g. `bed`, `cabinet`, `shelf`, `tv_monitor`), aligned from the ARKit frame into the laser-scan frame; each linked to its 2D projection via `fo.Instance`. |
| `tasks` | `ListField(StringField)` | All natural-language task descriptions for the scene. |

`ipad_N` slices (one video sample per recording):

| Field | FiftyOne type | Description |
|-------|---------------|-------------|
| `video_id` | `StringField` | 8-digit iPad sequence identifier (verbatim) of this recording. |
| `frames[n].timestamp` | `FloatField` | Capture timestamp of the frame. |
| `frames[n].depth` | `Heatmap` | Per-frame depth map (`map_path` to the source depth PNG in mm, `range` in mm). |
| `frames[n].intrinsics` | `DictField` | Per-frame camera intrinsics `{width, height, fx, fy, cx, cy}`. |
| `frames[n].camera_pose` | `ListField` | 4x4 camera-to-world pose (COLMAP, laser-scan frame), nearest-timestamp matched. |
| `frames[n].projected_elements` | `Detections` | 2D boxes of the functional elements visible in the frame (only on frames where an element projects); `instance` links each back to its 3D box. |
| `frames[n].projected_points` | `Keypoints` | The projected (subsampled) mask points of each visible element; same `instance` linkage. |
| `frames[n].projected_objects` | `Detections` | 2D boxes of the ARKit room-level objects visible in the frame; `instance` links each back to its `objects_3d` box. |

### `functional_elements` detection attributes

Each `Detection` in `functional_elements` carries:

| Attribute | Type | Description |
|-----------|------|-------------|
| `label` | `str` | Affordance class of the element (e.g. `rotate`, `key_press`, `tip_push`, `hook_turn`, `pinch_pull`, `plug_in`, `unplug`). |
| `location` | `[x, y, z]` | Center of the axis-aligned 3D box, in the Faro laser-scan coordinate frame. |
| `dimensions` | `[dx, dy, dz]` | Box size, derived from the extent of the masked points. |
| `rotation` | `[0, 0, 0]` | Axis-aligned boxes (no orientation estimated from the mask). |
| `annot_id` | `str` | Source annotation UUID. |
| `num_points` | `int` | Number of laser-scan points in the element's index mask. |
| `descriptions` | `list[str]` | Task instructions that reference this element. |
| `motion_type` | `str` | `trans` (translation) or `rot` (rotation). |
| `motion_dir` | `[x, y, z]` | Motion direction vector. |
| `motion_origin` | `[x, y, z]` | Motion origin point (laser-scan coordinate of `motion_origin_idx`). |
| `motion_viz_orient` | `str` | `inwards` / `outwards` orientation hint for visualizing the motion. |

The `label` is one of the 9 Gibsonian-inspired affordance categories (paper Tab. 1):

- `rotate` - adjusted by a rotary switch/knob (e.g. thermostat)
- `key_press` - surfaces of keys that can be pressed (e.g. remote, keyboard)
- `tip_push` - triggered by the tip of a finger (e.g. light switch)
- `hook_pull` - pulled by hooking up fingers (e.g. fridge handle)
- `pinch_pull` - pulled with a pinch movement (e.g. drawer knob)
- `hook_turn` - turned by hooking up fingers (e.g. door handle)
- `foot_push` - pushed by foot (e.g. trash-can pedal)
- `plug_in` - electrical power sources
- `unplug` - removing a plug from a socket

(The source also has an `exclude` category for elements whose geometry is poorly
captured, e.g. reflective materials; it is a don't-care mask, not an affordance,
and is dropped here.)


### What is not ingested

- **Low-res iPad stream** (`lowres_wide` / `lowres_depth`, 256x192 @ 60 FPS) is not
  imported; the hires stream is used as the single RGB video slice.
- **Remaining ARKit-legacy assets** (`arkit_mesh` reconstruction, `vga_wide`,
  `ultrawide` camera streams) are available from the source but not imported here.
  (The ARKit `3dod_annotation` objects and the Faro<->ARKit `transform` *are* now
  ingested - see `objects_3d`.)

## Dataset Creation

### Curation Rationale


Most 3D scene datasets label whole objects or object parts, which is only an
intermediate step toward agents that must actually interact with the functional
elements (knobs, handles, buttons) to accomplish tasks. Commodity RGB-D
reconstructions (ScanNet, Matterport) often fail to capture these small details,
so SceneFun3D leverages high-resolution Faro laser scans. It is also the first
dataset to link **Gibsonian** affordances (what an element affords, e.g. "press")
with **telic** affordances (the element's purpose in scene context, e.g. "turn on
the ceiling light") via natural-language task descriptions, plus motion parameters
describing how to interact.

### Source Data

#### Data Collection and Processing


Scenes are built on ARKitScenes captures. For each scene, multiple Faro Focus S70 laser scans (four on average) are combined under a common coordinate frame and
downsampled with a 5mm voxel size to preserve small functional parts while remaining tractable; extraneous points from transparent surfaces (e.g. windows)
are removed with DBSCAN and flagged by a binary crop mask. Each scene is also accompanied by iPad Pro (2020) video sequences (three on average) with RGB,
on-device LiDAR depth, and camera trajectory. Because the iPad data and the laser scan are in different coordinate frames, the authors register them (proxy high-resolution RGB-D reconstruction + Predator + multi-scale ICP) and provide
per-frame camera poses via rigid-body motion interpolation in SO(3) x R^3. Each scene's hires RGB-D recordings, poses, and intrinsics are ingested as the `ipad_N`
video slices of its group.

The dataset's official splits are 545 train / 80 val / 85 test scenes (710 total; ARKitScenes' validation set is used as the test set since its test set is private).
This FiftyOne build samples 10 scenes from each split as listed in the toolkit's benchmark scene lists.

#### Who are the source data producers?


The underlying RGB-D captures and Faro laser scans come from ARKitScenes (Apple), recorded with a 2020 iPad Pro and a Faro Focus S70 laser scanner. The functional,
motion, and language annotations were produced by the SceneFun3D authors and their annotation team.

### Annotations

<!-- If the dataset contains annotations which are not part of the initial data collection, use this section to describe them. -->

#### Annotation process

<!-- This section describes the annotation process. -->

Annotations were collected with a custom lightweight web-based tool that supports point-accurate selection on dense high-resolution point clouds (accelerated by a
Bounding Volume Hierarchy ray-caster, no GPU required), with the scene videos available to annotators for reference. For each functional interactive element,
annotators (1) select a Gibsonian affordance label, (2) annotate the instance mask at single-point accuracy, (3) select the motion type (translational or rotational)
with a motion-axis origin point and direction vector, and (4) provide free-form natural-language task descriptions that uniquely involve that element. Collected
descriptions are additionally rephrased for diversity using OpenAI's `gpt-3.5-turbo-instruct` and verified. Elements whose geometry (or whose parent
object) is poorly captured (e.g. reflective materials) are labeled `exclude` and omitted from the benchmark evaluation.

#### Who are the annotators?

<!-- This section describes the people or systems who created the annotations. -->

Human annotators organized by the SceneFun3D authors, using the custom web-based annotation tool. Task-description rephrasings are machine-generated
(`gpt-3.5-turbo-instruct`) and human-verified.

## Citation

**BibTeX:**

```bibtex
@inproceedings{delitzas2024scenefun3d,
  title={{SceneFun3D: Fine-Grained Functionality and Affordance Understanding in 3D Scenes}},
  author={Delitzas, Alexandros and Takmaz, Ayca and Tombari, Federico and Sumner, Robert and Pollefeys, Marc and Engelmann, Francis},
  booktitle={IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)},
  year={2024}
}
```

**APA:**

Delitzas, A., Takmaz, A., Tombari, F., Sumner, R., Pollefeys, M., & Engelmann, F.
(2024). SceneFun3D: Fine-Grained Functionality and Affordance Understanding in 3D
Scenes. In *IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)*.

## More Information

Built on ARKitScenes (https://github.com/apple/ARKitScenes). Toolkit and
documentation: https://scenefun3d.github.io. This FiftyOne build downloads, per
scene, the visit-level assets (laser scan, crop mask, annotations, descriptions,
motions) and, per recording, the hires RGB / depth / intrinsics / poses from the
SceneFun3D release mirror plus the ARKit `3dod_annotation` and Faro<->ARKit
`transform` (for `objects_3d`).