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exploratory-data-analysis

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Perform comprehensive exploratory data analysis on scientific data files across 200+ file formats. This skill should be used when analyzing any scientific data

About this skill

Exploratory Data Analysis

Overview

Perform comprehensive exploratory data analysis (EDA) on scientific data files across multiple domains. This skill provides automated file type detection, format-specific analysis, data quality assessment, and generates detailed markdown reports suitable for documentation and downstream analysis planning.

Key Capabilities:

  • Automatic detection and analysis of 200+ scientific file formats
  • Comprehensive format-specific metadata extraction
  • Data quality and integrity assessment
  • Statistical summaries and distributions
  • Visualization recommendations
  • Downstream analysis suggestions
  • Markdown report generation

When to Use This Skill

Use this skill when:

  • User provides a path to a scientific data file for analysis
  • User asks to "explore", "analyze", or "summarize" a data file
  • User wants to understand the structure and content of scientific data
  • User needs a comprehensive report of a dataset before analysis
  • User wants to assess data quality or completeness
  • User asks what type of analysis is appropriate for a file

Supported File Categories

The skill has comprehensive coverage of scientific file formats organized into six major categories:

1. Chemistry and Molecular Formats (60+ extensions)

Structure files, computational chemistry outputs, molecular dynamics trajectories, and chemical databases.

File types include: .pdb, .cif, .mol, .mol2, .sdf, .xyz, .smi, .gro, .log, .fchk, .cube, .dcd, .xtc, .trr, .prmtop, .psf, and more.

Reference file: references/chemistry_molecular_formats.md

2. Bioinformatics and Genomics Formats (50+ extensions)

Sequence data, alignments, annotations, variants, and expression data.

File types include: .fasta, .fastq, .sam, .bam, .vcf, .bed, .gff, .gtf, .bigwig, .h5ad, .loom, .counts, .mtx, and more.

Reference file: references/bioinformatics_genomics_formats.md

3. Microscopy and Imaging Formats (45+ extensions)

Microscopy images, medical imaging, whole slide imaging, and electron microscopy.

File types include: .tif, .nd2, .lif, .czi, .ims, .dcm, .nii, .mrc, .dm3, .vsi, .svs, .ome.tiff, and more.

Reference file: references/microscopy_imaging_formats.md

4. Spectroscopy and Analytical Chemistry Formats (35+ extensions)

NMR, mass spectrometry, IR/Raman, UV-Vis, X-ray, chromatography, and other analytical techniques.

File types include: .fid, .mzML, .mzXML, .raw, .mgf, .spc, .jdx, .xy, .cif (crystallography), .wdf, and more.

Reference file: references/spectroscopy_analytical_formats.md

5. Proteomics and Metabolomics Formats (30+ extensions)

Mass spec proteomics, metabolomics, lipidomics, and multi-omics data.

File types include: .mzML, .pepXML, .protXML, .mzid, .mzTab, .sky, .mgf, .msp, .h5ad, and more.

Reference file: references/proteomics_metabolomics_formats.md

6. General Scientific Data Formats (30+ extensions)

Arrays, tables, hierarchical data, compressed archives, and common scientific formats.

File types include: .npy, .npz, .csv, .xlsx, .json, .hdf5, .zarr, .parquet, .mat, .fits, .nc, .xml, and more.

Reference file: references/general_scientific_formats.md

Workflow

Step 1: File Type Detection

When a user provides a file path, first identify the file type:

  1. Extract the file extension
  2. Look up the extension in the appropriate reference file
  3. Identify the file category and format description
  4. Load format-specific information

Example:

User: "Analyze data.fastq"
→ Extension: .fastq
→ Category: bioinformatics_genomics
→ Format: FASTQ Format (sequence data with quality scores)
→ Reference: references/bioinformatics_genomics_formats.md

Step 2: Load Format-Specific Information

Based on the file type, read the corresponding reference file to understand:

  • Typical Data: What kind of data this format contains
  • Use Cases: Common applications for this format
  • Python Libraries: How to read the file in Python
  • EDA Approach: What analyses are appropriate for this data type

Search the reference file for the specific extension (e.g., search for "### .fastq" in bioinformatics_genomics_formats.md).

Step 3: Perform Data Analysis

Use the scripts/eda_analyzer.py script OR implement custom analysis:

Option A: Use the analyzer script

# The script automatically:
# 1. Detects file type
# 2. Loads reference information
# 3. Performs format-specific analysis
# 4. Generates markdown report

python scripts/eda_analyzer.py <filepath> [output.md]

Option B: Custom analysis in the conversation Based on the format information from the reference file, perform appropriate analysis:

For tabular data (CSV, TSV, Excel):

  • Load with pandas
  • Check dimensions, data types
  • Analyze missing values
  • Calculate summary statistics
  • Identify outliers
  • Check for duplicates

For sequence data (FASTA, FASTQ):

  • Count sequences
  • Analyze length distributions
  • Calculate GC content
  • Assess quality scores (FASTQ)

For images (TIFF, ND2, CZI):

  • Check dimensions (X, Y, Z, C, T)
  • Analyze bit depth and value range
  • Extract metadata (channels, timestamps, spatial calibration)
  • Calculate intensity statistics

For arrays (NPY, HDF5):

  • Check shape and dimensions
  • Analyze data type
  • Calculate statistical summaries
  • Check for missing/invalid values

Step 4: Generate Comprehensive Report

Create a markdown report with the following sections:

Required Sections:

  1. Title and Metadata

    • Filename and timestamp
    • File size and location
  2. Basic Information

    • File properties
    • Format identification
  3. File Type Details

    • Format description from reference
    • Typical data content
    • Common use cases
    • Python libraries for reading
  4. Data Analysis

    • Structure and dimensions
    • Statistical summaries
    • Quality assessment
    • Data characteristics
  5. Key Findings

    • Notable patterns
    • Potential issues
    • Quality metrics
  6. Recommendations

    • Preprocessing steps
    • Appropriate analyses
    • Tools and methods
    • Visualization approaches

Template Location

Use assets/report_template.md as a guide for report structure.

Step 5: Save Report

Save the markdown report with a descriptive filename:

  • Pattern: {original_filename}_eda_report.md
  • Example: experiment_data.fastqexperiment_data_eda_report.md

Detailed Format References

Each reference file contains comprehensive information for dozens of file types. To find information about a specific format:

  1. Identify the category from the extension
  2. Read the appropriate reference file
  3. Search for the section heading matching the extension (e.g., "### .pdb")
  4. Extract the format information

Reference File Structure

Each format entry includes:

  • Description: What the format is
  • Typical Data: What it contains
  • Use Cases: Common applications
  • Python Libraries: How to read it (with code examples)
  • EDA Approach: Specific analyses to perform

Example lookup:

### .pdb - Protein Data Bank
**Description:** Standard format for 3D structures of biological macromolecules
**Typical Data:** Atomic coordinates, residue information, secondary structure
**Use Cases:** Protein structure analysis, molecular visualization, docking
**Python Libraries:**
- `Biopython`: `Bio.PDB`
- `MDAnalysis`: `MDAnalysis.Universe('file.pdb')`
**EDA Approach:**
- Structure validation (bond lengths, angles)
- B-factor distribution
- Missing residues detection
- Ramachandran plots

Best Practices

Reading Reference Files

Reference files are large (10,000+ words each). To efficiently use them:

  1. Search by extension: Use grep to find the specific format
    import re
    with open('references/chemistry_molecu
    

Install exploratory-data-analysis in Claude Code & Claude Desktop

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Allowed tools

Tools this skill is permitted to call.

No restriction — this skill can use any tool.

Bundled files

assets/report_template.mdreferences/bioinformatics_genomics_formats.mdreferences/chemistry_molecular_formats.mdreferences/general_scientific_formats.mdreferences/microscopy_imaging_formats.mdreferences/proteomics_metabolomics_formats.mdreferences/spectroscopy_analytical_formats.mdscripts/eda_analyzer.py

FAQ

What does the exploratory-data-analysis skill do?

Perform comprehensive exploratory data analysis on scientific data files across 200+ file formats. This skill should be used when analyzing any scientific data file to understand its structure, content, quality, and characteristics. Automatically detects file type and generates detailed markdown reports with format-specific analysis, quality metrics, and downstream analysis recommendations. Covers chemistry, bioinformatics, microscopy, spectroscopy, proteomics, metabolomics, and general scientific data formats.

How do I install the exploratory-data-analysis skill?

Copy the skill folder into ~/.claude/skills (the Claude Code tab above does this in one command), or install it as a plugin.

Does the exploratory-data-analysis skill run scripts?

Yes, this skill bundles executable scripts. Review the source before installing.

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