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Step 4 / Model Evaluation
==========================
Produces *publication-quality* figures that can be pasted directly into
the thesis (Chapter 5 β Results / Discussion). Run AFTER 3_train_model.py.
Inputs
------
models/rf_model.pkl
models/feature_columns.json
data/processed.csv
Outputs
-------
figures/01_roc_curve.png ROC + AUC
figures/02_pr_curve.png Precision-Recall + AP
figures/03_calibration_curve.png Reliability diagram + Brier score
figures/04_threshold_sweep.png F1 / F2 / Precision / Recall vs threshold
figures/05_feature_importance.png Top-20 features (horizontal bar)
figures/06_confusion_matrix.png Confusion matrix at optimal F2 threshold
figures/threshold_sweep.csv Same data as 04 in machine-readable form
figures/evaluation_summary.json One-shot metrics blob for the thesis
Run: python scripts/4_evaluate_model.py
"""
from __future__ import annotations
import json
from datetime import datetime, timezone
from pathlib import Path
import joblib
import matplotlib
import numpy as np
import pandas as pd
matplotlib.use("Agg")
import matplotlib.pyplot as plt
from sklearn.calibration import calibration_curve
from sklearn.metrics import (
auc,
average_precision_score,
brier_score_loss,
confusion_matrix,
f1_score,
fbeta_score,
precision_recall_curve,
precision_score,
recall_score,
roc_curve,
)
ROOT = Path(__file__).resolve().parent.parent
MODEL_DIR = ROOT / "models"
DATA_DIR = ROOT / "data"
FIG_DIR = ROOT / "figures"
FIG_DIR.mkdir(exist_ok=True)
# ββ Matplotlib defaults β keep figures consistent across panels ββββββββββ
plt.rcParams.update({
"figure.figsize": (7.0, 4.5),
"figure.dpi": 120,
"savefig.dpi": 200,
"savefig.bbox": "tight",
"font.size": 11,
"axes.titlesize": 13,
"axes.labelsize": 11,
"legend.fontsize": 10,
"axes.spines.top": False,
"axes.spines.right": False,
"grid.alpha": 0.25,
"axes.axisbelow": True,
})
# ββ Load artefacts βββββββββββββββββββββββββββββββββββββββββββββββββββββββ
def _load() -> tuple:
model_path = MODEL_DIR / "rf_model.pkl"
feats_path = MODEL_DIR / "feature_columns.json"
data_path = DATA_DIR / "processed.csv"
for p in (model_path, feats_path, data_path):
if not p.exists():
raise FileNotFoundError(
f"Missing artefact: {p}. Run scripts/3_train_model.py first."
)
model = joblib.load(model_path)
feat_cols = json.loads(feats_path.read_text())
df = pd.read_csv(data_path)
df["time"] = pd.to_datetime(df["time"])
df = df.sort_values("time").reset_index(drop=True)
# Use the last 20% as test (same split as training).
cut = int(len(df) * 0.80)
test = df.iloc[cut:].reset_index(drop=True)
X = test[feat_cols].values
y = test["is_rain_event"].astype(int).values
proba = model.predict_proba(X)[:, 1]
return model, feat_cols, X, y, proba, test
# ββ Figure builders ββββββββββββββββββββββββββββββββββββββββββββββββββββββ
def plot_roc(y, proba) -> dict:
fpr, tpr, _ = roc_curve(y, proba)
auc_v = auc(fpr, tpr)
fig, ax = plt.subplots()
ax.plot(fpr, tpr, color="#0ea5e9", linewidth=2.0, label=f"RF (AUC = {auc_v:.3f})")
ax.plot([0, 1], [0, 1], "--", color="#9ca3af", linewidth=1.0, label="Random baseline")
ax.set_xlabel("False Positive Rate")
ax.set_ylabel("True Positive Rate")
ax.set_title("ROC Curve β rain-event classifier")
ax.legend(loc="lower right")
ax.grid(True)
fig.savefig(FIG_DIR / "01_roc_curve.png")
plt.close(fig)
return {"auc": float(auc_v)}
def plot_pr(y, proba) -> dict:
pr, rc, _ = precision_recall_curve(y, proba)
ap = average_precision_score(y, proba)
base_rate = float(y.mean())
fig, ax = plt.subplots()
ax.plot(rc, pr, color="#10b981", linewidth=2.0, label=f"RF (AP = {ap:.3f})")
ax.hlines(base_rate, 0, 1, colors="#9ca3af", linestyles="--",
label=f"Base rate = {base_rate:.3f}")
ax.set_xlabel("Recall")
ax.set_ylabel("Precision")
ax.set_title("PrecisionβRecall Curve")
ax.legend(loc="lower left")
ax.grid(True)
fig.savefig(FIG_DIR / "02_pr_curve.png")
plt.close(fig)
return {"average_precision": float(ap), "base_rate": base_rate}
def plot_calibration(y, proba) -> dict:
frac_pos, mean_pred = calibration_curve(y, proba, n_bins=10, strategy="quantile")
brier = brier_score_loss(y, proba)
fig, ax = plt.subplots()
ax.plot([0, 1], [0, 1], "--", color="#9ca3af", linewidth=1.0,
label="Perfectly calibrated")
ax.plot(mean_pred, frac_pos, marker="o", color="#f59e0b", linewidth=2.0,
label=f"RF (Brier = {brier:.3f})")
ax.set_xlabel("Mean predicted probability")
ax.set_ylabel("Fraction of positives (observed)")
ax.set_title("Reliability Diagram β model calibration")
ax.legend(loc="upper left")
ax.grid(True)
fig.savefig(FIG_DIR / "03_calibration_curve.png")
plt.close(fig)
return {"brier_score": float(brier)}
def plot_threshold_sweep(y, proba) -> dict:
thresholds = np.linspace(0.05, 0.95, 19)
rows = []
best_f2 = (-1.0, 0.5)
for thr in thresholds:
yp = (proba >= thr).astype(int)
f1 = f1_score(y, yp, zero_division=0)
f2 = fbeta_score(y, yp, beta=2.0, zero_division=0)
prec = precision_score(y, yp, zero_division=0)
rec = recall_score(y, yp, zero_division=0)
rows.append({
"threshold": thr, "f1": f1, "f2": f2,
"precision": prec, "recall": rec,
})
if f2 > best_f2[0]:
best_f2 = (f2, thr)
sweep = pd.DataFrame(rows)
sweep.to_csv(FIG_DIR / "threshold_sweep.csv", index=False)
fig, ax = plt.subplots()
ax.plot(sweep.threshold, sweep.precision, label="Precision", color="#0ea5e9", linewidth=2.0)
ax.plot(sweep.threshold, sweep.recall, label="Recall", color="#10b981", linewidth=2.0)
ax.plot(sweep.threshold, sweep.f1, label="F1", color="#f59e0b", linewidth=1.4, linestyle="--")
ax.plot(sweep.threshold, sweep.f2, label="F2", color="#ef4444", linewidth=2.0)
ax.axvline(best_f2[1], color="#ef4444", alpha=0.25, linestyle=":")
ax.set_xlabel("Decision threshold")
ax.set_ylabel("Score")
ax.set_title(f"Threshold sweep β best F2 = {best_f2[0]:.3f} @ Ο = {best_f2[1]:.2f}")
ax.legend(loc="lower left", ncols=4)
ax.grid(True)
fig.savefig(FIG_DIR / "04_threshold_sweep.png")
plt.close(fig)
return {"best_f2": float(best_f2[0]), "best_f2_threshold": float(best_f2[1])}
def plot_feature_importance(model, feat_cols, top_n: int = 20) -> dict:
imp = pd.Series(model.feature_importances_, index=feat_cols)
imp = imp.sort_values(ascending=True).tail(top_n)
fig, ax = plt.subplots(figsize=(7.0, 0.32 * len(imp) + 1.2))
ax.barh(imp.index, imp.values, color="#6366f1")
ax.set_xlabel("Importance (mean decrease in impurity)")
ax.set_title(f"Top {len(imp)} feature importances")
ax.grid(True, axis="x")
fig.savefig(FIG_DIR / "05_feature_importance.png")
plt.close(fig)
return {"feature_importance": imp.sort_values(ascending=False).to_dict()}
def plot_confusion(y, proba, threshold: float) -> dict:
yp = (proba >= threshold).astype(int)
cm = confusion_matrix(y, yp)
tn, fp, fn, tp = cm.ravel()
fig, ax = plt.subplots(figsize=(4.5, 4.0))
im = ax.imshow(cm, cmap="Blues")
for i in range(2):
for j in range(2):
ax.text(j, i, str(cm[i, j]), ha="center", va="center",
color="black" if cm[i, j] < cm.max() / 2 else "white",
fontsize=13, fontweight="bold")
ax.set_xticks([0, 1], ["No rain", "Rain"])
ax.set_yticks([0, 1], ["No rain", "Rain"])
ax.set_xlabel("Predicted label")
ax.set_ylabel("True label")
ax.set_title(f"Confusion matrix @ Ο = {threshold:.2f}")
fig.colorbar(im, ax=ax, fraction=0.046, pad=0.04)
fig.savefig(FIG_DIR / "06_confusion_matrix.png")
plt.close(fig)
return {"tn": int(tn), "fp": int(fp), "fn": int(fn), "tp": int(tp)}
# ββ Main βββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
def main() -> None:
print(f"[eval] loading artefacts from {MODEL_DIR}")
model, feat_cols, _, y, proba, _test = _load()
print(f"[eval] test set: {len(y)} samples ({int(y.sum())} positives, "
f"{(y.mean() * 100):.1f}% rain-event rate)")
summary = {
"generated_at": datetime.now(timezone.utc).isoformat(),
"n_test": len(y),
"n_positives": int(y.sum()),
"positive_rate": float(y.mean()),
"n_features": len(feat_cols),
}
summary["roc"] = plot_roc(y, proba)
summary["pr"] = plot_pr(y, proba)
summary["calibration"] = plot_calibration(y, proba)
sweep = plot_threshold_sweep(y, proba)
summary["threshold_sweep"] = sweep
summary["confusion"] = plot_confusion(y, proba, sweep["best_f2_threshold"])
top_importances = plot_feature_importance(model, feat_cols)
summary["top_features"] = list(top_importances["feature_importance"].keys())[:10]
out = FIG_DIR / "evaluation_summary.json"
out.write_text(json.dumps(summary, indent=2))
print(f"[eval] all figures written to {FIG_DIR}")
print(f"[eval] summary JSON: {out}")
print(f"[eval] best F2 = {sweep['best_f2']:.3f} at Ο = {sweep['best_f2_threshold']:.2f}")
print(f"[eval] ROC AUC = {summary['roc']['auc']:.3f}, "
f"PR AP = {summary['pr']['average_precision']:.3f}, "
f"Brier = {summary['calibration']['brier_score']:.3f}")
if __name__ == "__main__":
main()
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