Skill843 estrellas del repoactualizado 4d ago
experimental-design
# ClaudeWave Editorial Description The experimental-design skill guides users through rigorous scientific experiment planning, including research question formulation, study design selection across randomized trials and observational approaches, power analysis for sample size calculation, and control variable strategies. Use this skill when planning experiments, determining required sample sizes, or establishing appropriate controls and study designs. Do not use for executing experiments, analyzing collected data, or writing results.
Instalar en Claude Code
Copiargit clone --depth 1 https://github.com/beita6969/ScienceClaw /tmp/experimental-design && cp -r /tmp/experimental-design/skills/experimental-design ~/.claude/skills/experimental-designDespués abre una sesión nueva de Claude Code; el skill carga automáticamente.
Definición
SKILL.md
# Experimental Design Skill
Design rigorous, reproducible experiments across scientific disciplines.
## When to Use
- "Design an experiment to test..."
- "How many samples do I need?"
- "What controls should I include?"
- "Help me plan a clinical trial"
- "Is this experimental design valid?"
- Power analysis and sample size calculation
## When NOT to Use
- Running the actual experiment (use code-execution)
- Analyzing collected data (use scipy-analysis + statsmodels-stats)
- Writing up results (use paper-writing)
- Literature review (use literature-search)
## Design Components
### 1. Research Question and Hypotheses
- State clear, testable research question
- Formulate H0 and H1 (see hypothesis-gen skill)
- Define primary and secondary outcomes
### 2. Study Design Selection
| Design | When to Use | Strengths | Weaknesses |
|--------|------------|-----------|------------|
| RCT | Causal inference needed | Gold standard causality | Expensive, ethical limits |
| Factorial | Multiple factors | Tests interactions | Complex analysis |
| Crossover | Within-subject comparison | Reduced variability | Carryover effects |
| Quasi-experimental | Randomization impossible | Practical feasibility | Weaker causality |
| Observational (cohort) | Long-term outcomes | Natural setting | Confounding |
| Case-control | Rare outcomes | Efficient for rare events | Recall bias |
### 3. Power Analysis
```python
# Sample size calculation template (using scipy/statsmodels)
from statsmodels.stats.power import TTestIndPower
analysis = TTestIndPower()
n = analysis.solve_power(
effect_size=0.5, # Cohen's d (small=0.2, medium=0.5, large=0.8)
alpha=0.05, # Significance level
power=0.80, # Statistical power (commonly 0.80 or 0.90)
ratio=1.0, # Ratio of group sizes (n2/n1)
alternative='two-sided'
)
print(f"Required sample size per group: {int(n) + 1}")
```
Key parameters:
- **Effect size**: Expected magnitude of difference
- **Alpha**: Type I error rate (usually 0.05)
- **Power**: 1 - Type II error rate (usually 0.80-0.95)
- **Attrition**: Add 10-20% for expected dropout
### 4. Variable Control
- **Independent variables**: What you manipulate
- **Dependent variables**: What you measure
- **Confounding variables**: What could bias results
- **Control strategies**: Randomization, blocking, matching, blinding
### 5. Randomization
- Simple randomization (coin flip)
- Block randomization (balanced groups)
- Stratified randomization (balance key covariates)
- Cluster randomization (group-level assignment)
### 6. Blinding
- Single-blind: Participants unaware of assignment
- Double-blind: Participants and researchers unaware
- Triple-blind: Including data analysts
## Reproducibility Checklist
- [ ] Protocol pre-registered (OSF, ClinicalTrials.gov, PROSPERO)
- [ ] All materials/reagents specified with catalog numbers
- [ ] Detailed step-by-step procedure written
- [ ] Statistical analysis plan pre-specified
- [ ] Data management plan documented
- [ ] Raw data sharing plan established
- [ ] Code availability ensured
- [ ] Sample size justified with power analysis
- [ ] Randomization method specified
- [ ] Blinding procedures documented
- [ ] Inclusion/exclusion criteria defined
- [ ] Primary endpoint pre-specified
## Output Format
```
## Experimental Design: [Title]
**Research Question**: [Clear question]
**Design Type**: [RCT/Factorial/etc.]
### Participants/Samples
- Population: [target population]
- Inclusion: [criteria]
- Exclusion: [criteria]
- Sample Size: N=[total] ([n] per group) — Power=[X], alpha=[X], effect=[X]
### Groups
- Experimental: [treatment description]
- Control: [control description]
- Blinding: [single/double/triple/none]
### Variables
- IV: [variables]
- DV: [primary + secondary outcomes]
- Controls: [confounds and how addressed]
### Procedure
1. [Step-by-step protocol]
### Analysis Plan
- Primary: [statistical test]
- Secondary: [additional analyses]
- Multiple comparison correction: [method]
### Timeline
- [Phase 1]: [duration]
- [Phase 2]: [duration]
### Ethics
- IRB/IACUC requirements: [details]
- Consent procedure: [details]
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