Schematic illustration of the Uni-Mol+ framework
Uni-Mol+ is a model for quantum chemical property prediction. Firstly, given a 2D molecular graph, Uni-Mol+ generates an initial 3D conformation from inexpensive methods such as RDKit. Then, the initial conformation is iteratively optimized to its equilibrium conformation, and the optimized conformation is further used to predict the QC properties.
In the PCQM4MV2 benchmark, Uni-Mol+ outperforms previous SOTA methods by a large margin.
| Model Settings | # Layers | # Param. | Validation MAE | Model Checkpoint |
|---|---|---|---|---|
| Uni-Mol+ | 12 | 52.4 M | 0.0696 | link |
| Uni-Mol+ Large | 18 | 77 M | 0.0693 | link |
| Uni-Mol+ Small | 6 | 27.7 M | 0.0714 | link |
In the OC20 IS2RE benchmark, Uni-Mol+ outperforms previous SOTA methods by a large margin.
| Model Settings | # Layers | # Param. | Validation Mean MAE | Test Mean MAE | Model Checkpoint |
|---|---|---|---|---|---|
| Uni-Mol+ | 12 | 48.6 M | 0.4088 | 0.4143 | link |
- Uni-Core with pytorch > 2.0.0, check its Installation Documentation.
- rdkit==2022.09.3, install via
pip install rdkit==2022.09.3 - numba and pandas, install via
pip install numba pandas
First, download the data:
cd scripts
bash download.shSecond, covert the 3D SDF (training set only) to lmdb file:
cd pcqm4m-v2
python ../get_label3d_lmdb.pyFinally, generate the training, validation and test datasets:
python ../get_3d_lmdb.py train
python ../get_3d_lmdb.py valid
python ../get_3d_lmdb.py test-dev
python ../get_3d_lmdb.py test-challengeFirst, follow this page to download the OC20 IS2RE data.
Second, clean the download lmdb files by the following commands:
input_path="your_input_path" # The path to the original OC20 dataset
output_path="your_output_path"
python scripts/oc20_preprocess.py --input-path $input_path --out-path $output_path --split train
python scripts/oc20_preprocess.py --input-path $input_path --out-path $output_path --split valid
python scripts/oc20_preprocess.py --input-path $input_path --out-path $output_path --split test export data_path="your_data_path"
export results_path="your_result_path"
export weight_path="your_ckp_path"
export task=pcq # or "oc20" for oc20 task
export arch="unimol_plus_pcq_large" # or "unimol_plus_oc20_base" for oc20 arch
export batch_size=16
bash inference.sh test-dev # or other splits, OC20's test files are in ["test_id", "test_ood_ads", "test_ood_both", "test_ood_cat"]After infernece, you can use the scripts/make_pcq_test_dev_submission.py (or scripts/make_oc20_test_submission.py) to generate the submission files for the leaderboard evalution.
data_path="your_data_path"
save_dir="your_save_path"
lr=2e-4
batch_size=128 # per gpu batch size 128, we default use 8 GPUs
export arch="unimol_plus_pcq_large" # or "unimol_plus_pcq_base" if you use 12-layer model
bash train_pcq.sh $data_path $save_dir $lr $batch_sizedata_path="your_data_path"
save_dir="your_save_path"
lr=2e-4
batch_size=8 # per gpu batch size 8, we default use 8 GPUs
export arch="unimol_plus_oc20_base"
bash train_oc20.sh $data_path $save_dir $lr $batch_sizePlease kindly cite this paper if you use the data/code/model.
@misc{lu2023highly,
title={Highly Accurate Quantum Chemical Property Prediction with Uni-Mol+},
author={Shuqi Lu and Zhifeng Gao and Di He and Linfeng Zhang and Guolin Ke},
year={2023},
eprint={2303.16982},
archivePrefix={arXiv},
primaryClass={physics.chem-ph}
}
This project is licensed under the terms of the MIT license. See LICENSE for additional details.