Datasets:

btlam
/

VAVD

	---
	language:
	- vi
	license: cc-by-nc-4.0
	task_categories:
	- video-classification
	- image-to-video
	tags:
	- talking-face
	- landmark
	- lip-sync
	- vietnamese
	- audio-visual
	pretty_name: 'VAVD: Vietnamese Visual-Audio Dataset'
	size_categories:
	- 1K<n<10K
	---

	# Vietnamese Visual-Audio Dataset

	Vietnamese audio-visual landmark dataset designed for talking-face landmark generation. The dataset is curated to support efficient fine-tuning of the pretrained [IP-LAP](https://github.com/Weizhi-Zhong/IP_LAP) model on Vietnamese speakers.

	> Note: This dataset does not directly host video files. Instead, [`video_sources.csv`](video_sources.csv) provides the 123 public YouTube source URLs. The full dataset can be automatically downloaded and processed using [`download_dataset.py`](download_dataset.py).

	---

	## Dataset Summary

	\| Split \| Clips \| Speakers \|
	\|-------\|------:\|--------:\|
	\| Train \| 3,541 \| ~118 \|
	\| Val \| 338 \| ~66 \|
	\| Test \| 239 \| ~52 \|
	\| Total \| 4,118 \| 123 \|

	The dataset is constructed from two sources:

	- `vilap_dataset`: 1,630 clips from the main training set
	- `vilap_dataset_extra_10h`: 2,488 clips from the extended crawl

	The videos are collected from public Vietnamese YouTube sources, including news programs, interviews, and talk shows. Each sample is a short single-speaker clip of approximately 5 seconds, processed at 25 FPS.

	---

	## Quick Start

	```bash
	# 1. Clone the dataset repository from Hugging Face
	git clone https://huggingface.co/datasets/btlam2002/VAVD
	cd VAVD

	# 2. Install the required dependencies
	pip install yt-dlp mediapipe opencv-python librosa scipy numpy

	# 3. Download and process the full dataset
	# This automatically downloads videos, cuts clips, extracts faces, landmarks, and audio features
	python download_dataset.py --output ./vilap_data

	# Or download only the test split for a quick trial (~239 clips)
	python download_dataset.py --output ./vilap_data --splits test

	# Or process only specific videos
	python download_dataset.py --output ./vilap_data --video_ids 3p7dFrIx5bk xwsPD6xiPbI
	```

	The `download_dataset.py` pipeline automatically performs the following steps:

	1. Download videos from YouTube using `yt-dlp` with a maximum resolution of 720p.
	2. Cut clips into 5-second segments using `ffmpeg`.
	3. Extract face crops at 128×128 pixels using MediaPipe Face Detection.
	4. Extract landmarks using MediaPipe Face Mesh, including 74 pose landmarks and 57 content landmarks.
	5. Extract audio features, including 16 kHz WAV files and Mel-spectrogram `.npy` files following the IP-LAP convention.

	---

	## Video Sources

	All video URLs are listed in [`video_sources.csv`](video_sources.csv).

	\| Column \| Description \|
	\|--------\|-------------\|
	\| `video_id` \| YouTube video ID, also used as the speaker folder name \|
	\| `youtube_url` \| Full YouTube URL \|
	\| `title` \| Video title \|
	\| `channel` \| YouTube channel name \|
	\| `source` \| Dataset source, either `vilap_dataset` or `vilap_dataset_extra_10h` \|
	\| `n_train_clips` \| Number of clips in the training split \|
	\| `n_val_clips` \| Number of clips in the validation split \|
	\| `n_test_clips` \| Number of clips in the test split \|
	\| `n_total_clips` \| Total number of clips from the video \|

	Example:

	```csv
	video_id,youtube_url,title,channel,source,n_train_clips,n_val_clips,n_test_clips,n_total_clips
	3p7dFrIx5bk,https://www.youtube.com/watch?v=3p7dFrIx5bk,Chuyên gia phân tích...,VTV24,vilap_dataset,68,1,1,70
	```

	---

	## Directory Structure

	```text
	vilap_dataset/
	├── 02_clips/
	│ └── <speaker_id>/
	│ └── <speaker_id>_cNNNN.mp4 # raw clip, 25 FPS, 1280×720
	├── 03_face/
	│ └── <speaker_id>/<clip_id>/
	│ └── {frame_id}.png # 128×128 face crop
	├── 04_sketch/
	│ └── <speaker_id>/<clip_id>/
	│ └── {frame_id}.png # optional sketch image
	├── 05_landmark/
	│ └── <speaker_id>/<clip_id>/
	│ └── {frame_id}.npy # per-frame landmark dictionary
	└── 06_audio/
	└── <speaker_id>/<clip_id>/
	├── audio.npy # Mel-spectrogram, shape [T, 80]
	└── audio.wav # 16 kHz mono WAV file
	```

	---

	## Landmark Format

	Each `.npy` landmark file contains a Python dictionary and can be loaded with `allow_pickle=True`.

	```python
	d = np.load("05_landmark/spk/spk_c0000/0.npy", allow_pickle=True).item()
	# d.keys() → ['pose_landmarks', 'content_landmarks']
	```

	\| Field \| Points \| Description \|
	\|-------\|-------:\|-------------\|
	\| `pose_landmarks` \| 74 \| Jaw and upper-face structural landmarks \|
	\| `content_landmarks` \| 57 \| Lip and lower-face landmarks, including jaw `0:17`, outer lip `17:37`, and inner lip `37:57` \|

	Each landmark is stored as a list of `[landmark_id, x, y]` triplets, where `x` and `y` are normalized to the face crop range `[0.0, 1.0]`.

	```python
	# Example: read one frame
	import numpy as np

	d = np.load("frame_0.npy", allow_pickle=True).item()

	content = d["content_landmarks"] # list of [id, x, y], 57 points
	pose = d["pose_landmarks"] # list of [id, x, y], 74 points

	# Sort landmarks according to the IP-LAP ori_sequence_idx before feeding them into the model.
	```

	---

	## Audio Format

	\| Property \| Value \|
	\|----------\|-------\|
	\| Sample rate \| 16,000 Hz \|
	\| Channels \| Mono \|
	\| Mel bands \| 80 \|
	\| FFT size \| 800 \|
	\| Hop size \| 200 samples \|
	\| Frame rate \| 25 FPS, aligned with video \|

	```python
	# Load Mel-spectrogram
	mel = np.load("audio.npy") # shape: [T_mel_frames, 80]

	# Extract a 16-frame Mel window for frame i following the IP-LAP convention
	frame_idx = 50
	audio_offset = -2 # -4 recommended offset for Vietnamese speech

	start = int(80.0 * ((frame_idx + audio_offset) / 25.0))
	window = mel[start : start + 16, :] # shape: [16, 80]
	```

	---

	## File Lists

	The `filelists/` directory provides pre-computed train, validation, and test splits.

	```text
	filelists/
	├── train.txt # 3,541 clips, 86.0%
	├── val.txt # 338 clips, 8.2%
	└── test.txt # 239 clips, 5.8%
	```

	Each line stores a clip key in the format `<speaker_id>/<clip_id>`.

	```text
	3p7dFrIx5bk/3p7dFrIx5bk_c0000
	3p7dFrIx5bk/3p7dFrIx5bk_c0001
	...
	```

	The following example shows how to resolve the actual data paths:

	```python
	from pathlib import Path

	DATA_BASE = Path("path/to/vilap_dataset")

	clip_key = "3p7dFrIx5bk/3p7dFrIx5bk_c0017"
	dirname, vidname = clip_key.split("/")

	face_dir = DATA_BASE / "03_face" / dirname / vidname
	lm_dir = DATA_BASE / "05_landmark" / dirname / vidname
	audio_npy = DATA_BASE / "06_audio" / dirname / vidname / "audio.npy"
	audio_wav = DATA_BASE / "06_audio" / dirname / vidname / "audio.wav"
	```

	---

	## Loading a Full Clip

	```python
	import numpy as np
	import torch
	from pathlib import Path

	DATA_BASE = Path("vilap_dataset")

	ORI_SEQUENCE_IDX = [
	162, 127, 234, 93, 132, 58, 172, 136, 150, 149, 176, 148, 152,
	377, 400, 378, 379, 365, 397, 288, 361, 323, 454, 356, 389,
	70, 63, 105, 66, 107, 55, 65, 52, 53, 46,
	336, 296, 334, 293, 300, 276, 283, 282, 295, 285,
	168, 6, 197, 195, 5,
	48, 115, 220, 45, 4, 275, 440, 344, 278,
	33, 246, 161, 160, 159, 158, 157, 173, 133, 155, 154, 153, 145, 144, 163, 7,
	362, 398, 384, 385, 386, 387, 388, 466, 263, 249, 390, 373, 374, 380, 381, 382,
	61, 185, 40, 39, 37, 0, 267, 269, 270, 409, 291, 375, 321, 405, 314, 17, 84, 181, 91, 146,
	78, 191, 80, 81, 82, 13, 312, 311, 310, 415, 308, 324, 318, 402, 317, 14, 87, 178, 88, 95,
	]


	def load_clip(clip_key, data_base):
	dirname, vidname = clip_key.split("/")
	lm_dir = data_base / "05_landmark" / dirname / vidname

	npys = sorted(lm_dir.glob("*.npy"), key=lambda p: int(p.stem))
	frame_ids = [int(p.stem) for p in npys]

	pose_list, content_list = [], []

	for fid in frame_ids:
	d = np.load(lm_dir / f"{fid}.npy", allow_pickle=True).item()

	for key, pts, n in [
	("pose_landmarks", pose_list, 74),
	("content_landmarks", content_list, 57),
	]:
	lm = sorted(d[key], key=lambda t: ORI_SEQUENCE_IDX.index(int(t[0])))

	arr = torch.zeros(2, n)
	arr[0] = torch.tensor([float(t[1]) for t in lm])
	arr[1] = torch.tensor([float(t[2]) for t in lm])

	pts.append(arr)

	all_pose = torch.stack(pose_list) # shape: [N, 2, 74]
	all_content = torch.stack(content_list) # shape: [N, 2, 57]

	mel = np.load(data_base / "06_audio" / dirname / vidname / "audio.npy")

	return all_pose, all_content, mel, frame_ids


	pose, content, mel, fids = load_clip(
	"3p7dFrIx5bk/3p7dFrIx5bk_c0017",
	DATA_BASE,
	)

	print(
	f"Frames: {len(fids)}, "
	f"pose: {pose.shape}, "
	f"content: {content.shape}, "
	f"mel: {mel.shape}"
	)
	```

	---

	## Processing New Videos

	To generate the dataset from raw videos, use the pipeline provided in [`scripts/process_vilap_data_pipeline.py`](../../scripts/process_vilap_data_pipeline.py).

	```text
	Step 1: Download or prepare raw .mp4 videos → 02_clips/
	Step 2: Detect and crop faces → 03_face/
	Step 3: Generate sketches, optional → 04_sketch/
	Step 4: Extract MediaPipe landmarks → 05_landmark/
	Step 5: Extract and resample audio → 06_audio/
	```

	Requirements:

	- Python 3.10.2
	- `mediapipe`
	- `librosa`
	- `opencv-python`
	- `ffmpeg`

	For Mel-spectrogram extraction details consistent with IP-LAP, see [`scripts/preprocess_audio.py`](../../third_party/IP_LAP/preprocess/preprocess_audio.py).

	---
	<!--
	## Model

	The ViLAP model is a LoRA-based fine-tuned version of [IP-LAP](https://github.com/Weizhi-Zhong/IP_LAP) trained on the proposed Vietnamese dataset. Model checkpoints are released separately.

	\| Model \| LMD ↓ \| Mouth-MAE ↓ \| Pearson-r ↑ \|
	\|-------\|------:\|------------:\|------------:\|
	\| IP-LAP pretrained \| 0.01386 \| 0.01737 \| 0.462 \|
	\| LoRA Talk \| 0.01139 \| 0.01357 \| 0.522 \|
	-->
	---
	<!--
	## Citation

	```bibtex
	@misc{vilap2025,
	title = {ViLAP: Vietnamese Landmark-Audio-Pose Dataset for Talking Face Generation},
	year = {2025},
	note = {Hugging Face dataset},
	}
	```
	-->
	---

	## License

	This dataset is released under the Creative Commons Attribution-NonCommercial 4.0 International License, CC BY-NC 4.0.

	The original videos are sourced from publicly available YouTube content. The dataset is intended for research and non-commercial use only.