--- license: mit --- # Dataset Card for ogbg-molpcba ## Table of Contents - [Table of Contents](#table-of-contents) - [Dataset Description](#dataset-description) - [Dataset Summary](#dataset-summary) - [Supported Tasks and Leaderboards](#supported-tasks-and-leaderboards) - [External Use](#external-use) - [PyGeometric](#pygeometric) - [Dataset Structure](#dataset-structure) - [Data Properties](#data-properties) - [Data Fields](#data-fields) - [Data Splits](#data-splits) - [Additional Information](#additional-information) - [Licensing Information](#licensing-information) - [Citation Information](#citation-information) - [Contributions](#contributions) ## Dataset Description - **Homepage:** [Homepage](https://ogb.stanford.edu/docs/graphprop/#ogbg-mol) - **Repository:** [Repo](https://github.com/snap-stanford/ogb) - **Paper:**: Open Graph Benchmark: Datasets for Machine Learning on Graphs - **Leaderboard:**: [OGB leaderboard](https://ogb.stanford.edu/docs/leader_graphprop/#ogbg-molpcba) and [Papers with code leaderboard](https://paperswithcode.com/sota/graph-property-prediction-on-ogbg-molpcba) ### Dataset Summary The `ogbg-molpcba` dataset is a small molecular property prediction dataset, adapted from MoleculeNet by teams at Stanford, to be a part of the Open Graph Benchmark. ### Supported Tasks and Leaderboards `ogbg-molpcba` should be used for molecular property prediction (with 128 properties to predict, not all present for all graphs), a binary classification task. The score used is Average Precision (AP) averaged over the tasks. The associated leaderboards are here: [OGB leaderboard](https://ogb.stanford.edu/docs/leader_graphprop/#ogbg-molpcba) and [Papers with code leaderboard](https://paperswithcode.com/sota/graph-property-prediction-on-ogbg-molpcba). ## External Use ### PyGeometric To load in PyGeometric, do the following: ```python from datasets import load_dataset from torch_geometric.data import Data from torch_geometric.loader import DataLoader dataset = load_dataset("graphs-datasets/ogbg-molpcba") # For the train set (replace by valid or test as needed) graphs_list_pygeometric = [Data(graph) for graph in dataset["train"]] dataset_pygeometric = DataLoader(graphs_list_pygeometric) ``` ## Dataset Structure ### Data Properties | property | value | |---|---| | scale | medium | | #graphs | 437,929 | | average #nodes | 26.0 | | average #edges | 28.1 | | average node degree | 2.2 | | average cluster coefficient | 0.002 | | MaxSCC ratio | 0.999 | | graph diameter | 13.6 | ### Data Fields Each row of a given file is a graph, with: - `x` (list: #nodes x #node-features): nodes - `edge_index` (list: 2 x #edges): pairs of nodes constituting edges - `edge_attr` (list: #edges x #edge-features): for the aforementioned edges, contains their features - `y` (list: 1 x #labels): contains the number of labels available to predict (here 128 labels, equal to zero, one, or Nan if the property is not relevant for the graph) - `num_nodes` (int): number of nodes of the graph ### Data Splits This data comes from the PyGeometric version of the dataset provided by OGB, and follows the provided data splits. This information can be found back using ```python from ogb.graphproppred import PygGraphPropPredDataset dataset = PygGraphPropPredDataset(name = 'ogbg-molpcba') split_idx = dataset.get_idx_split() train = dataset[split_idx['train']] # valid, test ``` ## Additional Information ### Licensing Information The dataset has been released under MIT license. ### Citation Information ``` @inproceedings{hu-etal-2020-open, author = {Weihua Hu and Matthias Fey and Marinka Zitnik and Yuxiao Dong and Hongyu Ren and Bowen Liu and Michele Catasta and Jure Leskovec}, editor = {Hugo Larochelle and Marc Aurelio Ranzato and Raia Hadsell and Maria{-}Florina Balcan and Hsuan{-}Tien Lin}, title = {Open Graph Benchmark: Datasets for Machine Learning on Graphs}, booktitle = {Advances in Neural Information Processing Systems 33: Annual Conference on Neural Information Processing Systems 2020, NeurIPS 2020, December 6-12, 2020, virtual}, year = {2020}, url = {https://proceedings.neurips.cc/paper/2020/hash/fb60d411a5c5b72b2e7d3527cfc84fd0-Abstract.html}, } ``` ### Contributions Thanks to [@clefourrier](https://github.com/clefourrier) for adding this dataset.