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covid_analysis
Commit 9a51e5c3 authored by Joaquin Torres's avatar Joaquin Torres
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ready to implement the PR curves

parent 9fa990e0
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model_selection/cv_metric_gen.py
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......@@ -177,7 +177,6 @@ if __name__ == "__main__":
scores_sheets = {} # To store score dfs as sheets in the same excel file
for i, group in enumerate(['pre']): # 'post'
for j, method in enumerate(['']): # '', 'over_', 'under_'
# print(f"{group}-{method_names[j]}")
# Get train dataset based on group and method
X_train = data_dic['X_train_' + method + group]
y_train = data_dic['y_train_' + method + group]
......@@ -191,44 +190,44 @@ if __name__ == "__main__":
axes = [axes]
# Metric generation for each model
for model_idx, (model_name, model) in enumerate(models.items()):
if model_name == 'DT':
print(f"{group}-{method_names[j]}-{model_name}")
# Retrieve cv scores for our metrics of interest
scores = cross_validate(model, X_train, y_train, scoring=scorings, cv=cv, return_train_score=True, n_jobs=10)
# Save results of each fold
for metric_name in scorings.keys():
scores_df.loc[model_name + f'_{metric_name}']=list(np.around(np.array(scores[f"test_{metric_name}"]),4))
# Generate ROC curves
mean_fpr = np.linspace(0, 1, 100)
tprs, aucs = [], []
cmap = plt.get_cmap('tab10') # Colormap for stronger colors
# Loop through each fold in the cross-validation
for fold_idx, (train, test) in enumerate(cv.split(X_train, y_train)):
# Fit the model on the training data
model.fit(X_train[train], y_train[train])
# Use RocCurveDisplay to generate the ROC curve
roc_display = RocCurveDisplay.from_estimator(model, X_train[test], y_train[test],
name=f"ROC fold {fold_idx}", alpha=0.6, lw=2,
ax=axes[model_idx], color=cmap(fold_idx % 10))
# Interpolate the true positive rates to get a smooth curve
interp_tpr = np.interp(mean_fpr, roc_display.fpr, roc_display.tpr)
interp_tpr[0] = 0.0
# Append the interpolated TPR and AUC for this fold
tprs.append(interp_tpr)
aucs.append(roc_display.roc_auc)
# Plot the diagonal line representing random guessing
axes[model_idx].plot([0, 1], [0, 1], linestyle='--', lw=2, color='r', alpha=.8, label='Random guessing')
# Compute the mean of the TPRs
mean_tpr = np.mean(tprs, axis=0)
mean_tpr[-1] = 1.0
mean_auc = auc(mean_fpr, mean_tpr) # Calculate the mean AUC
# Plot the mean ROC curve with a thicker line and distinct color
axes[model_idx].plot(mean_fpr, mean_tpr, color='b', lw=4,
label=r'Mean ROC (AUC = %0.2f)' % mean_auc, alpha=.8)
# Set plot limits and title
axes[model_idx].set(xlim=[-0.05, 1.05], ylim=[-0.05, 1.05],
title=f"ROC Curve - {model_name} ({group}-{method_names[j]})")
axes[model_idx].legend(loc="lower right")
print(f"{group}-{method_names[j]}-{model_name}")
# Retrieve cv scores for our metrics of interest
scores = cross_validate(model, X_train, y_train, scoring=scorings, cv=cv, return_train_score=True, n_jobs=10)
# Save results of each fold
for metric_name in scorings.keys():
scores_df.loc[model_name + f'_{metric_name}']=list(np.around(np.array(scores[f"test_{metric_name}"]),4))
# ---------- Generate ROC curves ----------
mean_fpr = np.linspace(0, 1, 100)
tprs, aucs = [], []
cmap = plt.get_cmap('tab10') # Colormap
# Loop through each fold in the cross-validation (redoing cv for simplicity)
for fold_idx, (train, test) in enumerate(cv.split(X_train, y_train)):
# Fit the model on the training data
model.fit(X_train[train], y_train[train])
# Use RocCurveDisplay to generate the ROC curve
roc_display = RocCurveDisplay.from_estimator(model, X_train[test], y_train[test],
name=f"ROC fold {fold_idx}", alpha=0.6, lw=2,
ax=axes[model_idx], color=cmap(fold_idx % 10))
# Interpolate the true positive rates to get a smooth curve
interp_tpr = np.interp(mean_fpr, roc_display.fpr, roc_display.tpr)
interp_tpr[0] = 0.0
# Append the interpolated TPR and AUC for this fold
tprs.append(interp_tpr)
aucs.append(roc_display.roc_auc)
# Plot the diagonal line representing random guessing
axes[model_idx].plot([0, 1], [0, 1], linestyle='--', lw=2, color='r', alpha=.8, label='Random guessing')
# Compute the mean of the TPRs
mean_tpr = np.mean(tprs, axis=0)
mean_tpr[-1] = 1.0
mean_auc = auc(mean_fpr, mean_tpr) # Calculate the mean AUC
# Plot the mean ROC curve with a thicker line and distinct color
axes[model_idx].plot(mean_fpr, mean_tpr, color='b', lw=4,
label=r'Mean ROC (AUC = %0.2f)' % mean_auc, alpha=.8)
# Set plot limits and title
axes[model_idx].set(xlim=[-0.05, 1.05], ylim=[-0.05, 1.05],
title=f"ROC Curve - {model_name} ({group}-{method_names[j]})")
axes[model_idx].legend(loc="lower right")
# ---------- END ROC curves Generation ----------
# Store the DataFrame in the dictionary with a unique key for each sheet
sheet_name = f"{group}_{method_names[j]}"
scores_sheets[sheet_name] = scores_df
......
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