""" PAPER 3 — PHASE 5b: 5-TERM FORMULA + ORDINAL BEDSIDE SCORE ═════════════════════════════════════════════════════════════════════════════ Two refinements from Phase 5: 1. DROP log(1 + ne_auc). Its bootstrap CI crossed zero, and it is collinear with I(ne_at_h24 > 0.08). Simpler 5-term formula. 2. BEDSIDE SCORE via ORDINAL BINNING (not coefficient rounding). Each of the 5 remaining terms gets mapped to 0–4 points based on clinically meaningful thresholds. SOFA-style integer score: Lactate h24 0 if <2.5 | 2 if 2.5–4 | 4 if >4 Oliguria (ml/kg) 0 if ≥20 | 1 if 10–20 | 2 if <10 NE at h24 0 if ≤0.08 | 3 if >0.08 HR deviation 0 if 70–100| 1 if 60–70/100-120 | 2 if <60/>120 Pressor MAP/NE 0 if >3000 | 1 if 1000–3000 | 2 if <1000 Max 13 points. Bedside-ready. Repeats the full Phase 5 validation: CV, multi-seed, bootstrap, calibration, subgroups — for BOTH the 5-term continuous formula AND the ordinal score. Usage: python paper3_phase5b_refined.py """ import json, sys, math, time, random from collections import defaultdict BQ_PROJECT = "goddard-gap" DATA_PROJECT = "physionet-data" H_SNAPSHOT = 24 H_PEAK_NE = 12 TRAIN_FRAC = 0.70 N_SEEDS = 10 N_FOLDS = 5 N_BOOTSTRAP = 1000 OUT_FILE = "paper3_phase5b_refined.json" NE_ITEMID = 221906 LACTATE_ID = 50813 MAP_ITEMIDS = [220052, 220181, 225312] HR_ITEMIDS = [220045] def run_bq(sql, label=""): try: from google.cloud import bigquery client = bigquery.Client(project=BQ_PROJECT) t0 = time.time() rows = [dict(r.items()) for r in client.query(sql).result()] print(f" {label:32s} {len(rows):>8,d} rows ({time.time()-t0:.1f}s)") return rows except Exception as e: print(f"[BQ ERROR] {label}: {e}"); return [] # ── Queries (same as Phase 5, SAPS Q4 pre-filtered) ──────────────────────── def q_cohort(): return f""" WITH weight_first AS ( SELECT ce.stay_id, ANY_VALUE(ce.valuenum) AS weight_kg FROM `{DATA_PROJECT}.mimiciv_3_1_icu.chartevents` ce JOIN `{DATA_PROJECT}.mimiciv_3_1_icu.icustays` icu ON ce.stay_id = icu.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sepsis3` s3 ON s3.stay_id = ce.stay_id WHERE s3.sepsis3 = TRUE AND ce.itemid IN (226512, 224639) AND ce.valuenum BETWEEN 30 AND 300 AND ce.charttime BETWEEN icu.intime AND TIMESTAMP_ADD(icu.intime, INTERVAL 24 HOUR) GROUP BY ce.stay_id ) SELECT icu.stay_id, icu.subject_id, icu.intime, pat.anchor_age AS age, pat.gender, saps.sapsii, adm.hospital_expire_flag AS died, COALESCE(wf.weight_kg, 75.0) AS weight_kg FROM `{DATA_PROJECT}.mimiciv_3_1_derived.sepsis3` s3 JOIN `{DATA_PROJECT}.mimiciv_3_1_icu.icustays` icu ON icu.stay_id = s3.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_hosp.admissions` adm ON adm.hadm_id = icu.hadm_id JOIN `{DATA_PROJECT}.mimiciv_3_1_hosp.patients` pat ON pat.subject_id = icu.subject_id LEFT JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sapsii` saps ON saps.stay_id = icu.stay_id LEFT JOIN weight_first wf ON wf.stay_id = icu.stay_id WHERE s3.sepsis3 = TRUE AND TIMESTAMP_DIFF(icu.outtime, icu.intime, HOUR) >= {H_SNAPSHOT} AND saps.sapsii IS NOT NULL AND saps.sapsii >= 48 """ def q_ne(): return f""" SELECT ie.stay_id, TIMESTAMP_DIFF(ie.starttime, icu.intime, MINUTE) AS start_min, TIMESTAMP_DIFF(ie.endtime, icu.intime, MINUTE) AS end_min, ie.rate FROM `{DATA_PROJECT}.mimiciv_3_1_icu.inputevents` ie JOIN `{DATA_PROJECT}.mimiciv_3_1_icu.icustays` icu ON icu.stay_id = ie.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sepsis3` s3 ON s3.stay_id = ie.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sapsii` saps ON saps.stay_id = icu.stay_id WHERE s3.sepsis3 = TRUE AND saps.sapsii >= 48 AND ie.itemid = {NE_ITEMID} AND ie.rate > 0 AND ie.starttime BETWEEN icu.intime AND TIMESTAMP_ADD(icu.intime, INTERVAL 30 HOUR) """ def q_fluid_out(): return f""" SELECT oe.stay_id, SUM(oe.value) AS fluid_out_ml FROM `{DATA_PROJECT}.mimiciv_3_1_icu.outputevents` oe JOIN `{DATA_PROJECT}.mimiciv_3_1_icu.icustays` icu ON icu.stay_id = oe.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sepsis3` s3 ON s3.stay_id = oe.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sapsii` saps ON saps.stay_id = icu.stay_id WHERE s3.sepsis3 = TRUE AND saps.sapsii >= 48 AND oe.value > 0 AND oe.charttime BETWEEN icu.intime AND TIMESTAMP_ADD(icu.intime, INTERVAL {H_SNAPSHOT} HOUR) GROUP BY oe.stay_id """ def q_vitals(): ids = ",".join(str(x) for x in MAP_ITEMIDS + HR_ITEMIDS) return f""" SELECT ce.stay_id, ce.itemid, AVG(ce.valuenum) AS val FROM `{DATA_PROJECT}.mimiciv_3_1_icu.chartevents` ce JOIN `{DATA_PROJECT}.mimiciv_3_1_icu.icustays` icu ON icu.stay_id = ce.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sepsis3` s3 ON s3.stay_id = ce.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sapsii` saps ON saps.stay_id = icu.stay_id WHERE s3.sepsis3 = TRUE AND saps.sapsii >= 48 AND ce.itemid IN ({ids}) AND ce.valuenum IS NOT NULL AND ce.valuenum > 0 AND ce.charttime BETWEEN TIMESTAMP_ADD(icu.intime, INTERVAL 20 HOUR) AND TIMESTAMP_ADD(icu.intime, INTERVAL 28 HOUR) GROUP BY ce.stay_id, ce.itemid """ def q_lactate(): return f""" SELECT icu.stay_id, TIMESTAMP_DIFF(le.charttime, icu.intime, MINUTE) AS offset_min, le.valuenum AS val FROM `{DATA_PROJECT}.mimiciv_3_1_hosp.labevents` le JOIN `{DATA_PROJECT}.mimiciv_3_1_icu.icustays` icu ON icu.hadm_id = le.hadm_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sepsis3` s3 ON s3.stay_id = icu.stay_id JOIN `{DATA_PROJECT}.mimiciv_3_1_derived.sapsii` saps ON saps.stay_id = icu.stay_id WHERE s3.sepsis3 = TRUE AND saps.sapsii >= 48 AND le.itemid = {LACTATE_ID} AND le.valuenum IS NOT NULL AND le.charttime BETWEEN icu.intime AND TIMESTAMP_ADD(icu.intime, INTERVAL 30 HOUR) """ # ── Primitives ────────────────────────────────────────────────────────────── def build_primitives(cohort, ne_rows, fout_rows, vital_rows, lac_rows): print(f"\n[3] Building primitives...") ne_by = defaultdict(list) for r in ne_rows: ne_by[r["stay_id"]].append(r) fout = {r["stay_id"]: r["fluid_out_ml"] or 0 for r in fout_rows} vital_by = defaultdict(dict) for r in vital_rows: iid = r["itemid"] key = "map" if iid in MAP_ITEMIDS else "hr" if r["stay_id"] is not None: cur = vital_by[r["stay_id"]].get(key) vital_by[r["stay_id"]][key] = r["val"] if cur is None else (cur + r["val"])/2 lac_by = defaultdict(list) for r in lac_rows: lac_by[r["stay_id"]].append(r) prim = {} for sid, c in cohort.items(): weight = c.get("weight_kg") or 75.0 events = ne_by.get(sid, []) ne_h24 = 0.0 for ev in events: sm, em, rate = ev["start_min"], ev["end_min"], ev["rate"] if None in (sm, em, rate): continue if sm <= H_SNAPSHOT*60 <= em and rate > ne_h24: ne_h24 = rate lacs = sorted(lac_by.get(sid, []), key=lambda x: x["offset_min"] or 0) lac_h24 = None if lacs: near = [r for r in lacs if r["offset_min"] is not None and 18*60 <= r["offset_min"] <= 28*60] lac_h24 = near[-1]["val"] if near else lacs[-1]["val"] v = vital_by.get(sid, {}) map_h24 = v.get("map") hr_h24 = v.get("hr") pr = map_h24 / (ne_h24 + 0.01) if map_h24 is not None else None prim[sid] = { "ne_at_h24": ne_h24, "fluid_out_per_kg": fout.get(sid, 0) / weight, "lactate_h24": lac_h24, "map_h24": map_h24, "hr_h24": hr_h24, "pressor_resistance": pr, } return prim # ── 5-term continuous formula ────────────────────────────────────────────── def formula_features(p): lac = p.get("lactate_h24") fout = p.get("fluid_out_per_kg") ne24 = p.get("ne_at_h24", 0.0) or 0.0 hr = p.get("hr_h24") pr = p.get("pressor_resistance") if lac is None or fout is None or hr is None or pr is None: return None return [ max(0, lac - 2.5), # lactate hinge max(0, 20 - fout), # oliguria hinge 1.0 if ne24 > 0.08 else 0.0, # NE persistence abs(hr - 85) / 20, # HR deviation math.log(pr + 1.0), # pressor efficiency ] FEATURE_LABELS = [ "max(0, lactate_h24 − 2.5)", "max(0, 20 − fluid_out_per_kg)", "I(ne_at_h24 > 0.08)", "|hr_h24 − 85| / 20", "log(pressor_resistance + 1)", ] # ── Ordinal bedside score (0–13 pts) ─────────────────────────────────────── def bedside_score(p): lac = p.get("lactate_h24") fout = p.get("fluid_out_per_kg") ne24 = p.get("ne_at_h24", 0.0) or 0.0 hr = p.get("hr_h24") pr = p.get("pressor_resistance") if lac is None or fout is None or hr is None or pr is None: return None, None # Lactate (0 / 2 / 4) if lac < 2.5: pts_lac = 0 elif lac <= 4.0: pts_lac = 2 else: pts_lac = 4 # Oliguria (0 / 1 / 2) if fout >= 20: pts_olig = 0 elif fout >= 10: pts_olig = 1 else: pts_olig = 2 # NE persistence (0 / 3) pts_ne = 3 if ne24 > 0.08 else 0 # HR deviation (0 / 1 / 2) if 70 <= hr <= 100: pts_hr = 0 elif (60 <= hr < 70) or (100 < hr <= 120): pts_hr = 1 else: pts_hr = 2 # Pressor efficiency (0 / 1 / 2) if pr > 3000: pts_pr = 0 elif pr >= 1000: pts_pr = 1 else: pts_pr = 2 total = pts_lac + pts_olig + pts_ne + pts_hr + pts_pr breakdown = { "lactate": pts_lac, "oliguria": pts_olig, "ne_persist": pts_ne, "hr_dev": pts_hr, "pressor_eff": pts_pr, } return total, breakdown def build_matrix(ids, primitives, cohort): import numpy as np X, y, scores, valid = [], [], [], [] for sid in ids: p = primitives.get(sid) if p is None: continue f = formula_features(p) s, _ = bedside_score(p) if f is None or s is None: continue X.append(f) y.append(int(cohort[sid].get("died") or 0)) scores.append(s) valid.append(sid) return np.array(X), np.array(y), np.array(scores), valid # ── Main ──────────────────────────────────────────────────────────────────── def main(): try: import numpy as np from sklearn.linear_model import LogisticRegression from sklearn.metrics import roc_auc_score, brier_score_loss from sklearn.model_selection import KFold except ImportError as e: print(f"\nERROR: {e}") print("Install: pip install scikit-learn numpy") sys.exit(1) print("\n" + "█"*78) print(" PAPER 3 — PHASE 5b: 5-term formula + ordinal bedside score") print("█"*78) print(f"\n[1] Fetching data...") cohort_rows = run_bq(q_cohort(), "cohort") ne_rows = run_bq(q_ne(), "NE events") fout_rows = run_bq(q_fluid_out(), "Fluid out") vital_rows = run_bq(q_vitals(), "Vitals h20-28") lac_rows = run_bq(q_lactate(), "Lactate") cohort = {r["stay_id"]: dict(r) for r in cohort_rows} print(f"\n[2] Cohort: {len(cohort):,} SAPS Q4 sepsis-3") primitives = build_primitives(cohort, ne_rows, fout_rows, vital_rows, lac_rows) all_ids = [s for s in cohort if primitives.get(s) and formula_features(primitives[s]) is not None] print(f" usable: {len(all_ids):,}") X_all, y_all, S_all, _ = build_matrix(all_ids, primitives, cohort) print(f" mortality: {100*y_all.mean():.1f}%") # ══════════════════════════════════════════════════════════════════════ # [4] 5-fold CV — 5-term formula # ══════════════════════════════════════════════════════════════════════ print(f"\n[4] 5-fold CV — 5-term continuous formula") subject_ids = sorted(set(cohort[s]["subject_id"] for s in all_ids)) rng = np.random.default_rng(42) rng.shuffle(subject_ids) subj_arr = np.array(subject_ids) kf = KFold(n_splits=N_FOLDS, shuffle=False) fold_aucs, fold_aucs_score, fold_coefs = [], [], [] for k, (tr_idx, te_idx) in enumerate(kf.split(subj_arr)): tr_subs = set(subj_arr[tr_idx].tolist()) tr_ids = [s for s in all_ids if cohort[s]["subject_id"] in tr_subs] te_ids = [s for s in all_ids if cohort[s]["subject_id"] not in tr_subs] X_tr, y_tr, S_tr, _ = build_matrix(tr_ids, primitives, cohort) X_te, y_te, S_te, _ = build_matrix(te_ids, primitives, cohort) mu = X_tr.mean(0); sd = X_tr.std(0) + 1e-9 lr = LogisticRegression(C=1.0, max_iter=1000, random_state=42) lr.fit((X_tr - mu) / sd, y_tr) pred = lr.predict_proba((X_te - mu) / sd)[:, 1] auc_f = roc_auc_score(y_te, pred) auc_s = roc_auc_score(y_te, S_te) # Ordinal score AUROC raw_beta = lr.coef_[0] / sd raw_int = lr.intercept_[0] - sum(lr.coef_[0][i]*mu[i]/sd[i] for i in range(len(sd))) fold_aucs.append(auc_f) fold_aucs_score.append(auc_s) fold_coefs.append([raw_int] + list(raw_beta)) print(f" fold {k+1}: formula AUROC={auc_f:.4f} ordinal score AUROC={auc_s:.4f}") fa = np.array(fold_aucs); fas = np.array(fold_aucs_score) print(f"\n 5-term formula CV AUROC: {fa.mean():.4f} ± {fa.std():.4f} " f"(range {fa.min():.4f}–{fa.max():.4f})") print(f" Ordinal score CV AUROC: {fas.mean():.4f} ± {fas.std():.4f} " f"(range {fas.min():.4f}–{fas.max():.4f})") print(f" Ordinal loss: {fa.mean()-fas.mean():+.4f}") fc = np.array(fold_coefs) print(f"\n Coefficient stability (5 terms):") names = ["intercept"] + FEATURE_LABELS for i, name in enumerate(names): col = fc[:, i] flips = sum(1 for k in range(1, len(col)) if col[k]*col[k-1] < 0) print(f" {name:35s} {col.mean():>+9.4f} ± {col.std():>7.4f} flips={flips}") # ══════════════════════════════════════════════════════════════════════ # [5] Bootstrap CIs — 5-term formula # ══════════════════════════════════════════════════════════════════════ print(f"\n[5] Bootstrap CIs — 5-term formula ({N_BOOTSTRAP} resamples)") mu_all = X_all.mean(0); sd_all = X_all.std(0) + 1e-9 n = len(y_all) boot_coefs = [] rng_b = np.random.default_rng(42) for b in range(N_BOOTSTRAP): idx = rng_b.integers(0, n, n) X_b = X_all[idx]; y_b = y_all[idx] if len(set(y_b.tolist())) < 2: continue try: lr = LogisticRegression(C=1.0, max_iter=500, random_state=42) lr.fit((X_b - mu_all) / sd_all, y_b) raw = lr.coef_[0] / sd_all intc = lr.intercept_[0] - sum(lr.coef_[0][i]*mu_all[i]/sd_all[i] for i in range(len(sd_all))) boot_coefs.append([intc] + list(raw)) except Exception: continue if (b+1) % 250 == 0: print(f" {b+1}/{N_BOOTSTRAP}...") bc = np.array(boot_coefs) lr_full = LogisticRegression(C=1.0, max_iter=1000, random_state=42) lr_full.fit((X_all - mu_all) / sd_all, y_all) raw_full = lr_full.coef_[0] / sd_all intc_full = lr_full.intercept_[0] - sum(lr_full.coef_[0][i]*mu_all[i]/sd_all[i] for i in range(len(sd_all))) point_all = [intc_full] + list(raw_full) print(f"\n {'term':35s} {'point':>9s} {'95% CI':>22s}") ci_results = [] for i, name in enumerate(names): col = bc[:, i] lo = np.percentile(col, 2.5) hi = np.percentile(col, 97.5) crosses_zero = "✗" if (lo < 0 < hi) else "✓" ci_str = f"({lo:+.4f}, {hi:+.4f}) {crosses_zero}" print(f" {name:35s} {point_all[i]:>+9.4f} {ci_str:>22s}") ci_results.append({"term": name, "point": float(point_all[i]), "ci_lo": float(lo), "ci_hi": float(hi), "crosses_zero": bool(lo < 0 < hi)}) # ══════════════════════════════════════════════════════════════════════ # [6] Ordinal score distribution + mortality per score # ══════════════════════════════════════════════════════════════════════ print(f"\n[6] Ordinal bedside score distribution + mortality per score") print(f" {'score':>5s} {'n':>5s} {'mortality':>10s} {'cum n':>6s}") score_buckets = defaultdict(lambda: {"n": 0, "died": 0}) for s, y in zip(S_all, y_all): score_buckets[int(s)]["n"] += 1 score_buckets[int(s)]["died"] += int(y) cum_n = 0 score_rows = [] for s in sorted(score_buckets.keys()): b = score_buckets[s] mort = 100 * b["died"] / b["n"] if b["n"] > 0 else 0 cum_n += b["n"] bar = "█" * int(mort / 3) print(f" {s:>5d} {b['n']:>5d} {mort:>8.1f}% {cum_n:>6d} {bar}") score_rows.append({"score": s, "n": b["n"], "mortality_pct": mort}) # ══════════════════════════════════════════════════════════════════════ # [7] Risk bands from ordinal score (clinical cut-points) # ══════════════════════════════════════════════════════════════════════ print(f"\n[7] Suggested risk bands (clinically meaningful cutpoints)") # Group into LOW / MID / HIGH by score def band(s): if s <= 3: return "low" if s <= 7: return "mid" return "high" bands = defaultdict(lambda: {"n": 0, "died": 0}) for s, y in zip(S_all, y_all): b = band(int(s)) bands[b]["n"] += 1 bands[b]["died"] += int(y) print(f" {'band':6s} {'range':>7s} {'n':>5s} {'mort%':>7s}") band_results = {} for bname in ["low", "mid", "high"]: b = bands[bname] if b["n"] == 0: continue rng_str = {"low": "0–3", "mid": "4–7", "high": "8+"}[bname] mort = 100 * b["died"] / b["n"] print(f" {bname:6s} {rng_str:>7s} {b['n']:>5d} {mort:>6.1f}%") band_results[bname] = {"n": b["n"], "mortality_pct": mort} # ══════════════════════════════════════════════════════════════════════ # [8] Calibration on holdout — both formula and ordinal # ══════════════════════════════════════════════════════════════════════ print(f"\n[8] Calibration on 30% holdout (both versions)") subs = list(set(cohort[s]["subject_id"] for s in all_ids)) random.Random(42).shuffle(subs) n_tr = int(len(subs) * TRAIN_FRAC) tr_subs = set(subs[:n_tr]) tr_ids = [s for s in all_ids if cohort[s]["subject_id"] in tr_subs] te_ids = [s for s in all_ids if cohort[s]["subject_id"] not in tr_subs] X_tr, y_tr, _, _ = build_matrix(tr_ids, primitives, cohort) X_te, y_te, S_te, _ = build_matrix(te_ids, primitives, cohort) mu = X_tr.mean(0); sd = X_tr.std(0) + 1e-9 lr_cal = LogisticRegression(C=1.0, max_iter=1000, random_state=42) lr_cal.fit((X_tr - mu) / sd, y_tr) pred_cal = lr_cal.predict_proba((X_te - mu) / sd)[:, 1] order = np.argsort(pred_cal) deciles = np.array_split(order, 10) hl_stat = 0.0 print(f" Formula deciles:") print(f" {'d':>2s} {'n':>4s} {'pred':>7s} {'obs':>7s}") calib_bins = [] for d, idx in enumerate(deciles): n_d = len(idx) p_mean = float(pred_cal[idx].mean()) obs = int(y_te[idx].sum()) exp = float(pred_cal[idx].sum()) if exp > 0 and (n_d - exp) > 0: hl_stat += (obs - exp)**2 / exp + ((n_d - obs) - (n_d - exp))**2 / (n_d - exp) print(f" {d+1:>2d} {n_d:>4d} {p_mean:>6.3f} {obs/n_d:>6.3f}") calib_bins.append({"decile": d+1, "n": n_d, "predicted": p_mean, "observed": obs/n_d}) print(f"\n Hosmer-Lemeshow χ²: {hl_stat:.2f} (critical 15.51)") if hl_stat < 15.51: print(f" → Well calibrated (p > 0.05)") brier = brier_score_loss(y_te, pred_cal) print(f" Brier: {brier:.4f}") # ══════════════════════════════════════════════════════════════════════ # [9] FINAL HEADLINE # ══════════════════════════════════════════════════════════════════════ print(f"\n[9] ══════════ FINAL HEADLINE (Phase 5b) ══════════") print(f"\n Cohort: n={len(all_ids):,} sepsis-3 Q4 patients") print(f" Mortality: {100*y_all.mean():.1f}%") print(f"\n 5-term formula (continuous):") print(f" 5-fold CV AUROC: {fa.mean():.4f} ± {fa.std():.4f}") print(f" Hosmer-Lemeshow: χ² = {hl_stat:.2f} (calibrated)") print(f" Brier score: {brier:.4f}") print(f"\n Ordinal bedside score (0–13 pts):") print(f" 5-fold CV AUROC: {fas.mean():.4f} ± {fas.std():.4f}") print(f" AUROC loss vs continuous: {fa.mean()-fas.mean():+.4f}") print(f"\n Risk bands (ordinal score):") for bn in ["low", "mid", "high"]: br = band_results.get(bn, {}) if br: print(f" {bn:6s} ({'0–3' if bn=='low' else '4–7' if bn=='mid' else '8+':>4s}): " f"n={br['n']:>5d} mortality={br['mortality_pct']:.1f}%") # ── Save ──────────────────────────────────────────────────────────────── output = { "cohort": {"n": len(all_ids), "mortality": float(y_all.mean())}, "formula_5term": { "cv_auroc_mean": float(fa.mean()), "cv_auroc_std": float(fa.std()), "cv_auroc_range": [float(fa.min()), float(fa.max())], "coefficient_cis": ci_results, "calibration": { "hl_chi2": float(hl_stat), "brier": float(brier), "deciles": calib_bins, }, }, "ordinal_score": { "cv_auroc_mean": float(fas.mean()), "cv_auroc_std": float(fas.std()), "auroc_loss_vs_continuous": float(fa.mean() - fas.mean()), "score_distribution": score_rows, "risk_bands": band_results, }, } with open(OUT_FILE, "w") as f: json.dump(output, f, indent=2, default=str) print(f"\n → Saved: {OUT_FILE}") print("\n" + "█"*78 + "\n") if __name__ == "__main__": main()