review-data-analysis

pjt222

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Testsdata

À propos

Cette compétence de Claude examine les pipelines d'analyse de données pour en vérifier la qualité, l'exactitude et la reproductibilité. Elle effectue des contrôles de qualité des données, de validation des modèles, de vérification des hypothèses et de détection de fuites de données. Utilisez-la pour valider des pipelines de ML avant la mise en production, pour auditer des rapports destinés à la prise de décision, ou pour mener des examens par les pairs dans des environnements réglementés.

Installation rapide

Claude Code

Recommandé

Principal

npx skills add pjt222/agent-almanac -a claude-code

Commande PluginAlternatif

/plugin add https://github.com/pjt222/agent-almanac

Git CloneAlternatif

git clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/review-data-analysis

Copiez et collez cette commande dans Claude Code pour installer cette compétence

Documentation

Review Data Analysis

Evaluate a data analysis pipeline for correctness, robustness, and reproducibility.

When to Use

Reviewing a colleague's analysis notebook or script before publication
Validating a machine learning pipeline before production deployment
Auditing an analytical report for regulatory or business decision-making
Assessing whether an analysis supports its stated conclusions
Performing a second-analyst review in a regulated environment

Inputs

Required: Analysis code (scripts, notebooks, or pipeline definitions)
Required: Analysis output (results, tables, figures, model metrics)
Optional: Raw data or data dictionary
Optional: Analysis plan or protocol (pre-registered or ad-hoc)
Optional: Target audience and decision context

Procedure

Step 1: Assess Data Quality

Review the input data before evaluating the analysis:

## Data Quality Assessment

### Completeness
- [ ] Missing data quantified (% by column and by row)
- [ ] Missing data mechanism considered (MCAR, MAR, MNAR)
- [ ] Imputation method appropriate (if used) or complete-case analysis justified

### Consistency
- [ ] Data types match expectations (dates are dates, numbers are numbers)
- [ ] Value ranges are plausible (no negative ages, future dates in historical data)
- [ ] Categorical variables have expected levels (no misspellings, consistent coding)
- [ ] Units are consistent across records

### Uniqueness
- [ ] Duplicate records identified and handled
- [ ] Primary keys are unique where expected
- [ ] Join operations produce expected row counts (no fan-out or drop)

### Timeliness
- [ ] Data vintage appropriate for the analysis question
- [ ] Temporal coverage matches the study period
- [ ] No look-ahead bias in time-series data

### Provenance
- [ ] Data source documented
- [ ] Extraction date/version recorded
- [ ] Any transformations between source and analysis input documented

Got: Data quality issues documented with their potential impact on results. If fail: If data is not accessible for review, assess quality from the code (what checks and transformations are applied).

Step 2: Check Assumptions

For each statistical method or model used:

Method	Key Assumptions	How to Check
Linear regression	Linearity, independence, normality of residuals, homoscedasticity	Residual plots, Q-Q plot, Durbin-Watson, Breusch-Pagan
Logistic regression	Independence, no multicollinearity, linear logit	VIF, Box-Tidwell, residual diagnostics
t-test	Independence, normality (or large n), equal variance	Shapiro-Wilk, Levene's test, visual inspection
ANOVA	Independence, normality, homogeneity of variance	Shapiro-Wilk per group, Levene's test
Chi-squared	Independence, expected frequency ≥ 5	Expected frequency table
Random forest	Sufficient training data, feature relevance	OOB error, feature importance, learning curves
Neural network	Sufficient data, appropriate architecture, no data leakage	Validation curves, overfitting checks

## Assumption Check Results
| Analysis Step | Method | Assumption | Checked? | Result |
|---------------|--------|------------|----------|--------|
| Primary model | Linear regression | Normality of residuals | Yes | Q-Q plot shows mild deviation — acceptable for n>100 |
| Primary model | Linear regression | Homoscedasticity | No | Not checked — recommend adding Breusch-Pagan test |

Got: Every statistical method has its assumptions explicitly checked or acknowledged. If fail: If assumptions are violated, check whether the authors addressed this (robust methods, transformations, sensitivity analysis).

Step 3: Detect Data Leakage

Data leakage occurs when information from outside the training set influences the model, leading to over-optimistic performance:

Common leakage patterns:

Target leakage: Feature that directly encodes the target variable (e.g., "treatment_outcome" used to predict "treatment_success")
Temporal leakage: Future information used to predict the past (features computed from data that wouldn't be available at prediction time)
Train-test contamination: Preprocessing (scaling, imputation, feature selection) fitted on full dataset before splitting
Group leakage: Related observations (same patient, same device) split across train and test sets
Feature engineering leakage: Aggregates computed across the entire dataset rather than within the training fold

## Leakage Assessment
| Check | Status | Evidence |
|-------|--------|----------|
| Target leakage | Clear | No features derived from target |
| Temporal leakage | CONCERN | Feature X uses 30-day forward average |
| Train-test contamination | Clear | StandardScaler fit on train only |
| Group leakage | CONCERN | Patient IDs not used for stratified split |

Got: All common leakage patterns checked with clear/concern status. If fail: If leakage is found, estimate its impact by re-running without the leaked feature (if possible) or flag for the analyst to investigate.

Step 4: Validate Model Performance

For predictive models:

Appropriate metrics for the problem (not just accuracy — consider precision, recall, F1, AUC, RMSE, MAE)
Cross-validation or holdout strategy described and appropriate
Performance on training vs. test/validation set compared (overfitting check)
Baseline comparison provided (naive model, random chance, previous approach)
Confidence intervals or standard errors on performance metrics
Performance evaluated on relevant subgroups (fairness, edge cases)

For inferential/explanatory models:

Model fit statistics reported (R², AIC, BIC, deviance)
Coefficients interpreted correctly (direction, magnitude, significance)
Multicollinearity assessed (VIF < 5–10)
Influential observations identified (Cook's distance, leverage)
Model comparison if multiple specifications tested

Got: Model validation appropriate for the use case (prediction vs. inference). If fail: If test set performance is suspiciously close to training performance, flag potential leakage.

Step 5: Assess Reproducibility

## Reproducibility Checklist
| Item | Status | Notes |
|------|--------|-------|
| Code runs without errors | [Yes/No] | Tested on [environment description] |
| Random seeds set | [Yes/No] | Line [N] in [file] |
| Dependencies documented | [Yes/No] | requirements.txt / renv.lock present |
| Data loading reproducible | [Yes/No] | Path is [relative/absolute/URL] |
| Results match reported values | [Yes/No] | Verified: Table 1 ✓, Figure 2 ✗ (minor discrepancy) |
| Environment documented | [Yes/No] | Python 3.11 / R 4.5.0 specified |

Got: Reproducibility verified by re-running the analysis (or assessing from code if data is unavailable). If fail: If results don't reproduce exactly, determine if differences are within floating-point tolerance or indicate a problem.

Step 6: Write the Review

## Data Analysis Review

### Overall Assessment
[1-2 sentences: Is the analysis sound? Does it support the conclusions?]

### Data Quality
[Summary of data quality findings, impact on results]

### Methodological Concerns
1. **[Title]**: [Description, location in code/report, suggestion]
2. ...

### Strengths
1. [What was done well]
2. ...

### Reproducibility
[Tier assessment: Gold/Silver/Bronze/Opaque with justification]

### Recommendations
- [ ] [Specific action items for the analyst]

Got: Review provides actionable feedback with specific references to code locations. If fail: If time-constrained, prioritize data quality and leakage checks over style issues.

Validation

Data quality assessed across completeness, consistency, uniqueness, timeliness, provenance
Statistical assumptions checked for each method used
Data leakage systematically assessed
Model performance validated with appropriate metrics and baselines
Reproducibility evaluated (code runs, results match)
Feedback is specific, referencing code lines or report sections
Tone is constructive and collaborative

Pitfalls

Reviewing only the code: The analysis plan and conclusions matter as much as the implementation.
Ignoring data quality: Sophisticated models on bad data produce confident wrong answers.
Assuming correctness from complexity: A random forest with 95% accuracy might have data leakage; a simple t-test might be the correct approach.
Not running the code: If at all possible, execute the code to verify reproducibility. Reading code is not sufficient.
Missing the forest for the trees: Don't get lost in code style issues while missing a fundamental analytical error.

Related Skills

review-research — broader research methodology and manuscript review
validate-statistical-output — double-programming verification methodology
generate-statistical-tables — publication-ready statistical tables
review-software-architecture — code structure and design review

Dépôt GitHub

pjt222/agent-almanac

Chemin: i18n/caveman-lite/skills/review-data-analysis

agentsagentskillsai-assisted-developmentclaude-codeskillsteams

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