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Gaze-LLE

Gaze-LLE: Gaze Target Estimation via Large-Scale Learned Encoders
Fiona Ryan, Ajay Bati, Sangmin Lee, Daniel Bolya, Judy Hoffman*, James M. Rehg*

This is the official implementation for Gaze-LLE, a transformer approach for estimating gaze targets that leverages the power of pretrained visual foundation models. Gaze-LLE provides a streamlined gaze architecture that learns only a lightweight gaze decoder on top of a frozen, pretrained visual encoder (DINOv2). Gaze-LLE learns 1-2 orders of magnitude fewer parameters than prior works and doesn't require any extra input modalities like depth and pose!

Installation

Clone this repo, then create the virtual environment.

conda env create -f environment.yml
conda activate gazelle
pip install -e .

If your system supports it, consider installing xformers to speed up attention computation.

pip3 install -U xformers --index-url https://download.pytorch.org/whl/cu118

Pretrained Models

We provide the following pretrained models for download.

Name Backbone type Backbone name Training data Checkpoint
gazelle_dinov2_vitb14 DINOv2 ViT-B dinov2_vitb14 GazeFollow Download
gazelle_dinov2_vitl14 DINOv2 ViT-L dinov2_vitl14 GazeFollow Download
gazelle_dinov2_vitb14_inout DINOv2 ViT-B dinov2_vitb14 Gazefollow -> VideoAttentionTarget Download
gazelle_large_vitl14_inout DINOv2-ViT-L dinov2_vitl14 GazeFollow -> VideoAttentionTarget Download

Note that our Gaze-LLE checkpoints contain only the gaze decoder weights - the DINOv2 backbone weights are downloaded from facebookresearch/dinov2 on PyTorch Hub when the Gaze-LLE model is created in our code.

The GazeFollow-trained models output a spatial heatmap of gaze locations over the scene with values in range [0,1], where 1 represents the highest probability of the location being a gaze target. The models that are additionally finetuned on VideoAttentionTarget also predict a in/out of frame gaze score in range [0,1] where 1 represents the person's gaze target being in the frame.

PyTorch Hub

The models are also available on PyTorch Hub for easy use without installing from source.

model, transform = torch.hub.load('fkryan/gazelle', 'gazelle_dinov2_vitb14')
model, transform = torch.hub.load('fkryan/gazelle', 'gazelle_dinov2_vitl14')
model, transform = torch.hub.load('fkryan/gazelle', 'gazelle_dinov2_vitb14_inout')
model, transform = torch.hub.load('fkryan/gazelle', 'gazelle_dinov2_vitl14_inout')

Usage

Colab Demo Notebook

Check out our Demo Notebook on Google Colab for how to detect gaze for all people in an image.

Gaze Prediction

Gaze-LLE is set up for multi-person inference (e.g. for a single image, GazeLLE encodes the scene only once and then uses the features to predict the gaze of multiple people in the image). The input is a batch of image tensors and a list of bounding boxes for each image representing the heads of the people to predict gaze for in each image. The bounding boxes are tuples of form (xmin, ymin, xmax, ymax) and are in [0,1] normalized image coordinates. Below we show how to perform inference for a single person in a single image.

from PIL import Image
import torch
from gazelle.model import get_gazelle_model

model, transform = get_gazelle_model("gazelle_dinov2_vitl14_inout")
model.load_gazelle_state_dict(torch.load("/path/to/checkpoint.pt", weights_only=True))
model.eval()

device = "cuda" if torch.cuda.is_available() else "cpu"
model.to(device)

image = Image.open("path/to/image.png").convert("RGB")
input = {
    "images": transform(image).unsqueeze(dim=0).to(device),    # tensor of shape [1, 3, 448, 448]
    "bboxes": [[(0.1, 0.2, 0.5, 0.7)]]              # list of lists of bbox tuples
}

with torch.no_grad():
    output = model(input)
predicted_heatmap = output["heatmap"][0][0]        # access prediction for first person in first image. Tensor of size [64, 64]
predicted_inout = output["inout"][0][0]            # in/out of frame score (1 = in frame) (output["inout"] will be None  for non-inout models)

We empirically find that Gaze-LLE is effective without a bounding box input for scenes with just one person. However, providing a bounding box can improve results, and is necessary for scenes with multiple people to specify which person's gaze to estimate. To inference without a bounding box, use None in place of a bounding box tuple in the bbox list (e.g. input["bboxes"] = [[None]] in the example above).

We also provide a function to visualize the predicted heatmap for an image.

import matplotlib.pyplot as plt
from gazelle.utils import visualize_heatmap

viz = visualize_heatmap(image, predicted_heatmap)
plt.imshow(viz)
plt.show()

Evaluate

We provide evaluation scripts for GazeFollow and VideoAttentionTarget below to reproduce our results from our checkpoints.

GazeFollow

Download the GazeFollow dataset here. We provide a preprocessing script data_prep/preprocess_gazefollow.py, which preprocesses and compiles the annotations into a JSON file for each split within the dataset folder. Run the preprocessing script as

python data_prep/preprocess_gazefollow.py --data_path /path/to/gazefollow/data_new

Download the pretrained model checkpoints above and use --model_name and ckpt_path to specify the model type and checkpoint for evaluation.

python scripts/eval_gazefollow.py
    --data_path /path/to/gazefollow/data_new \
    --model_name gazelle_dinov2_vitl14 \
    --ckpt_path /path/to/checkpoint.pt \
    --batch_size 128

VideoAttentionTarget

Download the VideoAttentionTarget dataset here. We provide a preprocessing script data_prep/preprocess_vat.py, which preprocesses and compiles the annotations into a JSON file for each split within the dataset folder. Run the preprocessing script as

python data_prep/preprocess_gazefollow.py --data_path /path/to/videoattentiontarget

Download the pretrained model checkpoints above and use --model_name and ckpt_path to specify the model type and checkpoint for evaluation.

python scripts/eval_vat.py
    --data_path /path/to/videoattentiontarget \
    --model_name gazelle_dinov2_vitl14_inout \
    --ckpt_path /path/to/checkpoint.pt \
    --batch_size 64

Citation

@article{ryan2024gazelle,
  author       = {Ryan, Fiona and Bati, Ajay and Lee, Sangmin and Bolya, Daniel and Hoffman, Judy and Rehg, James M},
  title        = {Gaze-LLE: Gaze Target Estimation via Large-Scale Learned Encoders},
  journal      = {arXiv preprint arXiv:2412.09586},
  year         = {2024},
}

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