--- license: apache-2.0 language: - en tags: - NASA - Earth - Satellite - Knowledge Graph - Machine Learning --- # NASA Knowledge Graph Dataset ## Dataset Summary The **NASA Knowledge Graph Dataset** is an expansive graph-based dataset designed to integrate and interconnect information about satellite datasets, scientific publications, instruments, platforms, projects, data centers, and science keywords. This knowledge graph is particularly focused on datasets managed by NASA's Distributed Active Archive Centers (DAACs), which are NASA's data repositories responsible for archiving and distributing scientific data. In addition to NASA DAACs, the graph includes datasets from 184 data providers worldwide, including various government agencies and academic institutions. The primary goal of the NASA Knowledge Graph is to bridge scientific publications with the datasets they reference, facilitating deeper insights and research opportunities within NASA's scientific and data ecosystem. By organizing these interconnections within a graph structure, this dataset enables advanced analyses, such as discovering influential datasets, understanding research trends, and exploring scientific collaborations. ## Data Integrity Each file in the dataset has a SHA-256 checksum to verify its integrity: | File Name | SHA-256 Checksum | |----------------------------|---------------------------------------------------------------------------| | `graph.cypher` | `9159a04d385ccbd53858eaf21f4f80c9ce17b52ff997c410400ecc085bfbe010` | | `graph.graphml` | `2ca75302371f6be9fee1a051948144ba26147c1eebaea1e7a00dd1eb86ba2031` | | `graph.json` | `1dbeef75206edc3f893819589461b2a2ed9c1a14311dcc8aca304fb58c005ca1` | ### Verification To verify the integrity of each file, calculate its SHA-256 checksum and compare it with the hashes provided above. You can use the following Python code to calculate the SHA-256 checksum: ```python import hashlib def calculate_sha256(filepath): sha256_hash = hashlib.sha256() with open(filepath, "rb") as f: for byte_block in iter(lambda: f.read(4096), b""): sha256_hash.update(byte_block) return sha256_hash.hexdigest() ``` ## Dataset Structure ### Nodes and Properties The knowledge graph consists of seven main node types, each representing a different entity within NASA's ecosystem: #### 1. Dataset - **Description**: Represents satellite datasets, particularly those managed by NASA DAACs, along with datasets from other governmental and academic data providers. These nodes contain metadata and attributes specific to each dataset. - **Properties**: - `globalId` (String): Unique identifier for the dataset. - `doi` (String): Digital Object Identifier. - `shortName` (String): Abbreviated name of the dataset. - `longName` (String): Full name of the dataset. - `abstract` (String): Brief summary of the dataset. - `cmrId` (String): Common Metadata Repository ID. - `daac` (String): Distributed Active Archive Center associated with the dataset. - `temporalFrequency` (String): Frequency of data collection (e.g., daily, monthly). - `temporalExtentStart` (Date): Start date of the dataset's temporal coverage. - `temporalExtentEnd` (Date): End date of the dataset's temporal coverage. - `nwCorner` (Geo-Coordinate): Northwest corner coordinate of spatial coverage. - `seCorner` (Geo-Coordinate): Southeast corner coordinate of spatial coverage. - `landingPageUrl` (URL): Webpage link to the dataset. - `pagerank_global` (Float): PageRank score calculated using the natural graph direction. - `fastrp_embedding_with_labels` (List): FastRP embedding vector considering node labels. #### 2. Publication - **Description**: This node type captures publications that reference or use datasets, particularly those from NASA DAACs and other included data providers. By linking datasets and publications, this node type enables analysis of scientific impact and research usage of NASA’s datasets. - **Properties**: - `globalId` (String): Unique identifier for the publication. - `DOI` (String): Digital Object Identifier. - `title` (String): Title of the publication. - `abstract` (String): Summary of the publication's content. - `authors` (List): List of authors. - `year` (Integer): Year of publication. - `pagerank_global` (Float): PageRank score. - `fastrp_embedding_with_labels` (List): FastRP embedding vector. #### 3. ScienceKeyword - **Description**: Represents scientific keywords used to classify datasets and publications. Keywords provide topical context and aid in identifying research trends and related areas. - **Properties**: - `globalId` (String): Unique identifier. - `name` (String): Name of the science keyword. - `pagerank_global` (Float): PageRank score. - `fastrp_embedding_with_labels` (List): FastRP embedding vector. #### 4. Instrument - **Description**: Instruments used in data collection, often mounted on platforms like satellites. Instruments are linked to the datasets they help generate. - **Properties**: - `globalId` (String): Unique identifier. - `shortName` (String): Abbreviated name. - `longName` (String): Full name. - `pagerank_global` (Float): PageRank score. - `fastrp_embedding_with_labels` (List): FastRP embedding vector. #### 5. Platform - **Description**: Platforms, such as satellites or airborne vehicles, that host instruments for data collection. - **Properties**: - `globalId` (String): Unique identifier. - `shortName` (String): Abbreviated name. - `longName` (String): Full name. - `Type` (String): Type of platform. - `pagerank_global` (Float): PageRank score. - `fastrp_embedding_with_labels` (List): FastRP embedding vector. #### 6. Project - **Description**: NASA projects associated with datasets, often indicating a funding source or collaborative initiative for data collection and research. - **Properties**: - `globalId` (String): Unique identifier. - `shortName` (String): Abbreviated name. - `longName` (String): Full name. - `pagerank_global` (Float): PageRank score. - `fastrp_embedding_with_labels` (List): FastRP embedding vector. #### 7. DataCenter - **Description**: Represents data centers, primarily NASA DAACs, as well as other data providers in academia and government who manage and distribute datasets. - **Properties**: - `globalId` (String): Unique identifier. - `shortName` (String): Abbreviated name. - `longName` (String): Full name. - `url` (URL): Website of the data center. - `pagerank_global` (Float): PageRank score. - `fastrp_embedding_with_labels` (List): FastRP embedding vector. ### Relationships The knowledge graph includes several relationship types that define how nodes are interconnected. #### 1. HAS_DATASET - **Description**: Connects a `DataCenter` to its `Dataset(s)`. - **Properties**: None. #### 2. OF_PROJECT - **Description**: Links a `Dataset` to a `Project`. - **Properties**: None. #### 3. HAS_PLATFORM - **Description**: Associates a `Dataset` with a `Platform`. - **Properties**: None. #### 4. HAS_INSTRUMENT - **Description**: Connects a `Platform` to an `Instrument`. - **Properties**: None. #### 5. HAS_SCIENCEKEYWORD - **Description**: Links a `Dataset` to a `ScienceKeyword`. - **Properties**: None. #### 6. HAS_SUBCATEGORY - **Description**: Defines hierarchical relationships between `ScienceKeyword` nodes. - **Properties**: None. #### 7. CITES - **Description**: Represents citation relationships between `Publication` nodes, indicating how research builds on previous work. - **Properties**: None. #### 8. HAS_APPLIED_RESEARCH_AREA - **Description**: Associates a `Publication` with a `ScienceKeyword`. - **Properties**: None. ## Statistics - **Total Nodes**: **135,764** - **Publication**: 125,939 - **Dataset**: 6,390 - **ScienceKeyword**: 1,609 - **Instrument**: 867 - **Platform**: 442 - **Project**: 333 - **DataCenter**: 184 - **Total Relationships**: **344,525** - **CITES**: 208,670 - **HAS_APPLIED_RESEARCH_AREA**: 89,039 - **HAS_SCIENCEKEYWORD**: 20,436 - **HAS_PLATFORM**: 9,884 - **HAS_DATASET**: 9,017 - **OF_PROJECT**: 6,049 - **HAS_INSTRUMENT**: 2,469 - **HAS_SUBCATEGORY**: *(Count not provided)* ## Data Formats The Knowledge Graph Dataset is available in three formats: ### 1. JSON - **File**: `graph.json` - **Description**: A hierarchical data format representing nodes and relationships. Each node includes its properties, such as `globalId`, `doi`, and `pagerank_global`. - **Usage**: Suitable for web applications and APIs, and for use cases where hierarchical data structures are preferred. #### Loading the JSON Format To load the JSON file into a graph database that supports Cypher and the APOC library, use the following command: ```cypher CALL apoc.load.json("path/to/graph.json") YIELD value MERGE (n {id: value.id, label: value.label}) SET n += value.properties ``` ### 2. GraphML - **File**: `graph.graphml` - **Description**: An XML-based format well-suited for complex graph structures and metadata-rich representations. - **Usage**: Compatible with graph visualization and analysis tools, including Gephi, Cytoscape, and databases that support GraphML import. #### Loading the GraphML Format To import the GraphML file into a graph database with APOC support, use the following command: ```cypher CALL apoc.import.graphml("path/to/graph.graphml", {readLabels: true}) ``` ### 3. Cypher - **File**: `graph.cypher` - **Description**: A series of Cypher commands to recreate the knowledge graph structure. - **Usage**: Useful for recreating the graph in any Cypher-compatible graph database. #### Loading the Cypher Format To load the Cypher script, execute it directly using a command-line interface for your graph database: ```bash neo4j-shell -file path/to/graph.cypher ``` ### 4. Loading the Knowledge Graph into PyTorch Geometric (PyG) This knowledge graph can be loaded into PyG (PyTorch Geometric) for further processing, analysis, or model training. Below is an example script that shows how to load the JSON data into a PyG-compatible `HeteroData` object. The script first reads the JSON data, processes nodes and relationships, and then loads everything into a `HeteroData` object for use with PyG. ```python import json import torch from torch_geometric.data import HeteroData from collections import defaultdict # Load JSON data from file file_path = "path/to/graph.json" # Replace with your actual file path graph_data = [] with open(file_path, "r") as f: for line in f: try: graph_data.append(json.loads(line)) except json.JSONDecodeError as e: print(f"Error decoding JSON line: {e}") continue # Initialize HeteroData object data = HeteroData() # Mapping for node indices per node type node_mappings = defaultdict(dict) # Temporary storage for properties to reduce concatenation cost node_properties = defaultdict(lambda: defaultdict(list)) edge_indices = defaultdict(lambda: defaultdict(list)) # Process each item in the loaded JSON data for item in graph_data: if item['type'] == 'node': node_type = item['labels'][0] # Assuming first label is the node type node_id = item['id'] properties = item['properties'] # Store the node index mapping node_index = len(node_mappings[node_type]) node_mappings[node_type][node_id] = node_index # Store properties temporarily by type for key, value in properties.items(): if isinstance(value, list) and all(isinstance(v, (int, float)) for v in value): node_properties[node_type][key].append(torch.tensor(value, dtype=torch.float)) elif isinstance(value, (int, float)): node_properties[node_type][key].append(torch.tensor([value], dtype=torch.float)) else: node_properties[node_type][key].append(value) # non-numeric properties as lists elif item['type'] == 'relationship': start_type = item['start']['labels'][0] end_type = item['end']['labels'][0] start_id = item['start']['id'] end_id = item['end']['id'] edge_type = item['label'] # Map start and end node indices start_idx = node_mappings[start_type][start_id] end_idx = node_mappings[end_type][end_id] # Append to edge list edge_indices[(start_type, edge_type, end_type)]['start'].append(start_idx) edge_indices[(start_type, edge_type, end_type)]['end'].append(end_idx) # Finalize node properties by batch processing for node_type, properties in node_properties.items(): data[node_type].num_nodes = len(node_mappings[node_type]) for key, values in properties.items(): if isinstance(values[0], torch.Tensor): data[node_type][key] = torch.stack(values) else: data[node_type][key] = values # Keep non-tensor properties as lists # Finalize edge indices in bulk for (start_type, edge_type, end_type), indices in edge_indices.items(): edge_index = torch.tensor([indices['start'], indices['end']], dtype=torch.long) data[start_type, edge_type, end_type].edge_index = edge_index # Display statistics for verification print("Nodes and Properties:") for node_type in data.node_types: print(f"\nNode Type: {node_type}") print(f"Number of Nodes: {data[node_type].num_nodes}") for key, value in data[node_type].items(): if key != 'num_nodes': if isinstance(value, torch.Tensor): print(f" - {key}: {value.shape}") else: print(f" - {key}: {len(value)} items (non-numeric)") print("\nEdges and Types:") for edge_type in data.edge_types: edge_index = data[edge_type].edge_index print(f"Edge Type: {edge_type} - Number of Edges: {edge_index.size(1)} - Shape: {edge_index.shape}") ``` --- ## Citation Please cite the dataset as follows: **NASA Goddard Earth Sciences Data and Information Services Center (GES-DISC).** (2024). *Knowledge Graph of NASA Earth Observations Satellite Datasets and Related Research Publications* [Data set]. DOI: [10.57967/hf/3463](https://doi.org/10.57967/hf/3463) ### BibTeX ```bibtex @misc {nasa_goddard_earth_sciences_data_and_information_services_center__(ges-disc)_2024, author = { {NASA Goddard Earth Sciences Data and Information Services Center (GES-DISC)} }, title = { nasa-eo-knowledge-graph (Revision b8f650e) }, year = 2024, url = { https://huggingface.co./datasets/nasa-gesdisc/nasa-eo-knowledge-graph }, doi = { 10.57967/hf/3463 }, publisher = { Hugging Face } } ``` ## References For details on the process of collecting these publications, please refer to: Gerasimov, I., Savtchenko, A., Alfred, J., Acker, J., Wei, J., & KC, B. (2024). *Bridging the Gap: Enhancing Prominence and Provenance of NASA Datasets in Research Publications.* Data Science Journal, 23(1). DOI: [10.5334/dsj-2024-001](https://doi.org/10.5334/dsj-2024-001) For any questions or further information, please contact: - Armin Mehrabian: [armin.mehrabian@nasa.gov](mailto:armin.mehrabian@nasa.gov) - Irina Gerasimov: [irina.gerasimov@nasa.gov](mailto:irina.gerasimov@nasa.gov) - Kendall Gilbert: [kendall.c.gilbert@nasa.gov](mailto:kendall.c.gilbert@nasa.gov)