File size: 3,036 Bytes
2edd4a1 65b0414 2edd4a1 65b0414 2edd4a1 65b0414 2edd4a1 65b0414 2edd4a1 65b0414 | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 | ---
title: DoE & Bayesian Optimization Dashboard
emoji: π¬
colorFrom: indigo
colorTo: purple
sdk: gradio
sdk_version: "6.13.0"
app_file: app.py
pinned: true
license: mit
short_description: Design experiments & get AI-guided suggestions
tags:
- bayesian-optimization
- design-of-experiments
- gaussian-process
- machine-learning
- scientific-computing
---
# π¬ Design of Experiments & Bayesian Optimization Dashboard
A comprehensive tool for experimentalists to plan experiments, fit surrogate models, and get AI-guided suggestions for the next most informative experiments.
## Features
### π Design of Experiments
- **Full Factorial** β All combinations of factor levels
- **Fractional Factorial (Β½, ΒΌ)** β Reduced experiment count for screening
- **Latin Hypercube Sampling (LHS)** β Space-filling design for BO initialization
- **Sobol Sequence** β Low-discrepancy quasi-random design
- **Central Composite Design (CCD)** β Response surface methodology
- **Box-Behnken** β Efficient 3+ factor designs
- Flexible factor definition: comma-separated levels or range notation (`10:30:3`)
- Add/remove rows and columns dynamically
- CSV export
### π€ Surrogate Models
- **Gaussian Process** with 5 kernel choices (MatΓ©rn 5/2, MatΓ©rn 3/2, RBF, Rational Quadratic, RBF+MatΓ©rn)
- **Random Forest** with tree-ensemble uncertainty
- **Extra Trees** β faster RF variant
- **Gradient Boosting** with staged prediction uncertainty
### π― Acquisition Functions
- **Expected Improvement (EI)** β balanced exploration/exploitation
- **Probability of Improvement (PI)** β greedy exploitation
- **Upper Confidence Bound (UCB)** β tunable exploration weight
- **Thompson Sampling** β stochastic batch selection
- Diverse suggestion selection (avoids clustering)
### π 12 Visualization Types (all toggleable)
1. πΊοΈ Surrogate Surface (2D contour with mean + uncertainty)
2. π 1D Parameter Slices (effect of each factor)
3. ποΈ 3D Response Surface (interactive Plotly)
4. π― Acquisition Function Landscape
5. π Convergence Plot (best-so-far trajectory)
6. βοΈ Predicted vs Actual (parity plot with RΒ²/RMSE)
7. π Feature Importance (GP lengthscales / RF importances)
8. π Residual Analysis (residuals, histogram, Q-Q plot)
9. π Parallel Coordinates (interactive Plotly)
10. π‘οΈ Uncertainty Heatmap
11. π Correlation Matrix
12. π Scatter Matrix (pair plot)
## Workflow
1. **Define Factors** β Set experimental parameters and levels
2. **Generate Design** β Choose a design type (factorial, LHS, CCD, etc.)
3. **Run Experiments** β Fill in the Response column with results
4. **Fit Surrogate** β Configure model (GP/RF/ET/GB) and acquisition function
5. **Get Suggestions** β Receive optimized next-experiment recommendations
6. **Iterate** β Add suggestions to table, run them, repeat
## Tech Stack
- Gradio (UI), scikit-learn (GP, RF, ET, GB), scikit-optimize, scipy (LHS, Sobol, acquisition optimization), Plotly + Matplotlib (visualizations)
|