Revert "Expose maketitle by just using \input"

fix path

.github/workflows/latex-lint.yml

@@ -0,0 +1,52 @@
+name: LaTeX Lint
+
+on:
+  push:
+    branches:
+      - main
+      - dev
+    paths:
+      - 'latex/**/*.tex'
+      - 'latex/main.tex'
+  workflow_dispatch:
+  
+jobs:
+  lint:
+    runs-on: ubuntu-latest
+
+    steps:
+      - name: Checkout repository
+        uses: actions/checkout@v4
+
+      - name: Install chktex
+        run: |
+          sudo apt-get update
+          sudo apt-get install -y chktex
+
+      - name: Run chktex inside latex/
+        working-directory: latex
+        run: |
+          TEX_FILES=$(find . -type f -name "*.tex")
+          if [ -z "$TEX_FILES" ]; then
+            echo "No .tex files found in latex/. Skipping lint."
+            exit 0
+          fi
+          
+          echo "🔍 Linting .tex files with chktex..."
+          FAIL=0
+          
+          for f in $TEX_FILES; do
+            echo "▶ Checking $f"
+            # Run chktex and show output; capture error status
+            if ! chktex "$f"; then
+              echo "::warning file=$f::ChkTeX found issues in $f"
+              FAIL=1
+            fi
+          done
+          
+          if [ $FAIL -ne 0 ]; then
+            echo "::error::❌ Lint errors or warnings were found in one or more .tex files above."
+            exit 1
+          else
+            echo "✅ All files passed chktex lint."
+          fi

.github/workflows/latexdiff.yml

@@ -0,0 +1,89 @@
+name: LaTeX Diff
+
+on:
+  workflow_dispatch:
+    inputs:
+      base_branch:
+        description: 'Base branch (older version)'
+        required: true
+      compare_branch:
+        description: 'Compare branch (new version)'
+        required: true
+
+jobs:
+  latexdiff:
+    runs-on: ubuntu-latest
+    container:
+      image: ghcr.io/xu-cheng/texlive-full:latest
+      options: --user root
+
+    steps:
+      - name: Install latexpand (Perl script)
+        run: |
+          tlmgr init-usertree
+          tlmgr install latexpand
+        
+      - name: Checkout base branch
+        uses: actions/checkout@v4
+        with:
+          ref: ${{ github.event.inputs.base_branch }}
+          path: base
+
+      - name: Checkout compare branch
+        uses: actions/checkout@v4
+        with:
+          ref: ${{ github.event.inputs.compare_branch }}
+          path: compare
+
+
+      - name: Create output folder
+        run: mkdir -p diff_output
+
+      - name: Flatten base/main.tex (with latexpand)
+        run: |
+          cd base/latex
+          echo "📂 Listing files in base/latex:"
+          ls -R
+          echo "🔄 Flattening with latexpand..."
+          latexpand --verbose --keep-comments --output=../../diff_output/base_flat.tex main.tex
+          echo "✅ Preview of base_flat.tex:"
+          head -n 50 ../../diff_output/base_flat.tex
+
+
+      - name: Flatten compare/main.tex (with latexpand)
+        run: |
+          cd compare/latex
+          echo "📂 Listing files in compare/latex:"
+          ls -R
+          echo "🔄 Flattening with latexpand..."
+          latexpand --verbose --keep-comments --output=../../diff_output/compare_flat.tex main.tex
+          echo "✅ Preview of compare_flat.tex:"
+          head -n 50 ../../diff_output/compare_flat.tex
+
+      - name: Generate diff.tex using latexdiff
+        run: |
+          latexdiff diff_output/base_flat.tex diff_output/compare_flat.tex > diff_output/diff.tex
+          
+      - name: Upload flattened .tex and diff.tex early
+        uses: actions/upload-artifact@v4
+        with:
+          name: latex-diff-tex
+          path: |
+            diff_output/base_flat.tex
+            diff_output/compare_flat.tex
+            diff_output/diff.tex
+            
+      - name: Copy thesis.cls to diff_output
+        run: cp compare/latex/thesis.cls diff_output/
+        
+      - name: Compile diff.tex to PDF
+        working-directory: diff_output
+        run: |
+          xelatex -interaction=nonstopmode diff.tex
+          xelatex -interaction=nonstopmode diff.tex
+
+      - name: Upload diff output files
+        uses: actions/upload-artifact@v4
+        with:
+          name: latex-diff-output
+          path: diff_output/

.github/workflows/latexmk.yml

@@ -0,0 +1,29 @@
+name: Render XeLaTeX on PR to dev
+
+on:
+  pull_request:
+    branches:
+      - dev
+
+jobs:
+  build-pdf:
+    runs-on: ubuntu-latest
+
+    steps:
+      - name: Checkout repository
+        uses: actions/checkout@v4
+
+      - name: Compile XeLaTeX
+        uses: dante-ev/latex-action@2021-A
+        with:
+          root_file: main.tex
+          working_directory: latex
+          compiler: xelatex
+          args: -interaction=nonstopmode -halt-on-error -file-line-error
+          extra_system_packages: "fonts-freefont-otf"
+
+      - name: Upload compiled PDF
+        uses: actions/upload-artifact@v4
+        with:
+          name: compiled-pdf
+          path: latex/main.pdf

.vscode/settings.json

@@ -1,7 +1,4 @@
 {
-  "python.analysis.extraPaths": [
-    "./code/src/features",
-    "${workspaceFolder}/code/src"
-  ],
+  "python.analysis.extraPaths": ["./code/src/features"],
   "jupyter.notebookFileRoot": "${workspaceFolder}/code"
 }

code/notebooks/stft.ipynb

@@ -17,8 +17,8 @@
    "metadata": {},
    "outputs": [],
    "source": [
-    "sensor1 = pd.read_csv('D:/thesis/data/converted/raw/DAMAGE_1/DAMAGE_0_TEST1_01.csv',sep=',')\n",
-    "sensor2 = pd.read_csv('D:/thesis/data/converted/raw/DAMAGE_1/DAMAGE_0_TEST1_02.csv',sep=',')"
+    "sensor1 = pd.read_csv('D:/thesis/data/converted/raw/DAMAGE_1/DAMAGE_1_TEST1_01.csv',sep=',')\n",
+    "sensor2 = pd.read_csv('D:/thesis/data/converted/raw/DAMAGE_1/DAMAGE_1_TEST1_02.csv',sep=',')"
    ]
   },
   {
@@ -101,16 +101,13 @@
    "source": [
     "# Combined Plot for sensor 1 and sensor 2 from data1 file in which motor is operated at 800 rpm\n",
     "\n",
-    "plt.plot(df1['s2'], label='Sensor 1', color='C1', alpha=0.6)\n",
-    "plt.plot(df1['s1'], label='Sensor 2', color='C0', alpha=0.6)\n",
+    "plt.plot(df1['s2'], label='sensor 2')\n",
+    "plt.plot(df1['s1'], label='sensor 1', alpha=0.5)\n",
     "plt.xlabel(\"Number of samples\")\n",
     "plt.ylabel(\"Amplitude\")\n",
     "plt.title(\"Raw vibration signal\")\n",
     "plt.ylim(-7.5, 5)\n",
     "plt.legend()\n",
-    "plt.locator_params(axis='x', nbins=8)\n",
-    "plt.ylim(-1, 1)  # Adjust range as needed\n",
-    "plt.grid(True, linestyle='--', alpha=0.5)\n",
     "plt.show()"
    ]
   },
@@ -337,44 +334,8 @@
    "metadata": {},
    "outputs": [],
    "source": [
-    "import numpy as np\n",
-    "import matplotlib.pyplot as plt\n",
-    "from mpl_toolkits.mplot3d import Axes3D\n",
-    "\n",
-    "# Assuming ready_data1a[0] is a DataFrame or 2D array\n",
-    "spectrogram_data = ready_data1a[0].values  # Convert to NumPy array if it's a DataFrame\n",
-    "\n",
-    "# Get the dimensions of the spectrogram\n",
-    "num_frequencies, num_time_frames = spectrogram_data.shape\n",
-    "\n",
-    "# Create frequency and time arrays\n",
-    "frequencies = np.arange(num_frequencies)  # Replace with actual frequency values if available\n",
-    "time_frames = np.arange(num_time_frames)  # Replace with actual time values if available\n",
-    "\n",
-    "# Create a meshgrid for plotting\n",
-    "T, F = np.meshgrid(time_frames, frequencies)\n",
-    "\n",
-    "# Create a 3D plot\n",
-    "fig = plt.figure(figsize=(12, 8))\n",
-    "ax = fig.add_subplot(111, projection='3d')\n",
-    "\n",
-    "# Plot the surface\n",
-    "surf = ax.plot_surface(T, F, spectrogram_data, cmap='bwr', edgecolor='none')\n",
-    "\n",
-    "# Add labels and a color bar\n",
-    "ax.set_xlabel('Time Frames')\n",
-    "ax.set_ylabel('Frequency [Hz]')\n",
-    "ax.set_zlabel('Magnitude')\n",
-    "ax.set_title('3D Spectrogram')\n",
-    "# Resize the z-axis (shrink it)\n",
-    "z_min, z_max = 0, 0.1  # Replace with your desired range\n",
-    "ax.set_zlim(z_min, z_max)\n",
-    "ax.get_proj = lambda: np.dot(Axes3D.get_proj(ax), np.diag([1, 1, 0.5, 1]))  # Shrink z-axis by 50%\n",
-    "ax.set_facecolor('white')\n",
-    "fig.colorbar(surf, ax=ax, shrink=0.5, aspect=10)\n",
-    "\n",
-    "# Show the plot\n",
-    "plt.show()"
+    "len(ready_data1a)\n",
+    "# plt.pcolormesh(ready_data1[0])"
    ]
   },
   {
@@ -383,32 +344,12 @@
    "metadata": {},
    "outputs": [],
    "source": [
-    "from cmcrameri import cm\n",
-    "# Create a figure and subplots\n",
-    "fig, axes = plt.subplots(2, 3, figsize=(15, 8), sharex=True, sharey=True)\n",
-    "\n",
-    "# Flatten the axes array for easier iteration\n",
-    "axes = axes.flatten()\n",
-    "\n",
-    "# Loop through each subplot and plot the data\n",
     "for i in range(6):\n",
-    "    pcm = axes[i].pcolormesh(ready_data1a[i].transpose(), cmap='bwr', vmax=0.03, vmin=0.0)\n",
-    "    axes[i].set_title(f'Case {i} Sensor A', fontsize=12)\n",
-    "\n",
-    "# Add a single color bar for all subplots\n",
-    "# Use the first `pcolormesh` object (or any valid one) for the color bar\n",
-    "cbar = fig.colorbar(pcm, ax=axes, orientation='vertical')\n",
-    "# cbar.set_label('Magnitude')\n",
-    "\n",
-    "# Set shared labels\n",
-    "fig.text(0.5, 0.04, 'Time Frames', ha='center', fontsize=12)\n",
-    "fig.text(0.04, 0.5, 'Frequency [Hz]', va='center', rotation='vertical', fontsize=12)\n",
-    "\n",
-    "# Adjust layout\n",
-    "# plt.tight_layout(rect=[0.05, 0.05, 1, 1])  # Leave space for shared labels\n",
-    "plt.subplots_adjust(left=0.1, right=0.75, top=0.9, bottom=0.1, wspace=0.2, hspace=0.2)\n",
-    "\n",
-    "plt.show()"
+    "    plt.pcolormesh(ready_data1a[i])\n",
+    "    plt.title(f'STFT Magnitude for case {i} sensor 1')\n",
+    "    plt.xlabel(f'Frequency [Hz]')\n",
+    "    plt.ylabel(f'Time [sec]')\n",
+    "    plt.show()"
    ]
   },
   {
@@ -594,8 +535,8 @@
    "metadata": {},
    "outputs": [],
    "source": [
-    "len(y_data[0])\n",
-    "# y_data"
+    "# len(y_data[0])\n",
+    "y_data"
    ]
   },
   {
@@ -633,16 +574,6 @@
     "X2a, y = create_ready_data('D:/thesis/data/converted/raw/sensor2')"
    ]
   },
-  {
-   "cell_type": "code",
-   "execution_count": null,
-   "metadata": {},
-   "outputs": [],
-   "source": [
-    "X1a.iloc[-1,:]\n",
-    "# y[2565]"
-   ]
-  },
   {
    "cell_type": "code",
    "execution_count": null,
@@ -688,24 +619,137 @@
    "metadata": {},
    "outputs": [],
    "source": [
-    "from src.ml.model_selection import train_and_evaluate_model\n",
-    "from sklearn.svm import SVC\n",
-    "# Define models for sensor1\n",
-    "models_sensor1 = {\n",
-    "    # \"Random Forest\": RandomForestClassifier(),\n",
-    "    # \"Bagged Trees\": BaggingClassifier(estimator=DecisionTreeClassifier(), n_estimators=10),\n",
-    "    # \"Decision Tree\": DecisionTreeClassifier(),\n",
-    "    # \"KNN\": KNeighborsClassifier(),\n",
-    "    # \"LDA\": LinearDiscriminantAnalysis(),\n",
-    "    \"SVM\": SVC(),\n",
-    "    # \"XGBoost\": XGBClassifier()\n",
-    "}\n",
+    "accuracies1 = []\n",
+    "accuracies2 = []\n",
     "\n",
-    "results_sensor1 = []\n",
-    "for name, model in models_sensor1.items():\n",
-    "    res = train_and_evaluate_model(model, name, \"sensor1\", x_train1, y_train, x_test1, y_test, export='D:/thesis/models/sensor1')\n",
-    "    results_sensor1.append(res)\n",
-    "    print(f\"{name} on sensor1: Accuracy = {res['accuracy']:.2f}%\")\n"
+    "\n",
+    "# 1. Random Forest\n",
+    "rf_model1 = RandomForestClassifier()\n",
+    "rf_model1.fit(x_train1, y_train)\n",
+    "rf_pred1 = rf_model1.predict(x_test1)\n",
+    "acc1 = accuracy_score(y_test, rf_pred1) * 100\n",
+    "accuracies1.append(acc1)\n",
+    "# format with color coded if acc1 > 90\n",
+    "acc1 = f\"\\033[92m{acc1:.2f}\\033[00m\" if acc1 > 90 else f\"{acc1:.2f}\"\n",
+    "print(\"Random Forest Accuracy for sensor 1:\", acc1)\n",
+    "rf_model2 = RandomForestClassifier()\n",
+    "rf_model2.fit(x_train2, y_train)\n",
+    "rf_pred2 = rf_model2.predict(x_test2)\n",
+    "acc2 = accuracy_score(y_test, rf_pred2) * 100\n",
+    "accuracies2.append(acc2)\n",
+    "# format with color coded if acc2 > 90\n",
+    "acc2 = f\"\\033[92m{acc2:.2f}\\033[00m\" if acc2 > 90 else f\"{acc2:.2f}\"\n",
+    "print(\"Random Forest Accuracy for sensor 2:\", acc2)\n",
+    "# print(rf_pred)\n",
+    "# print(y_test)\n",
+    "\n",
+    "# 2. Bagged Trees\n",
+    "bagged_model1 = BaggingClassifier(estimator=DecisionTreeClassifier(), n_estimators=10)\n",
+    "bagged_model1.fit(x_train1, y_train)\n",
+    "bagged_pred1 = bagged_model1.predict(x_test1)\n",
+    "acc1 = accuracy_score(y_test, bagged_pred1) * 100\n",
+    "accuracies1.append(acc1)\n",
+    "# format with color coded if acc1 > 90\n",
+    "acc1 = f\"\\033[92m{acc1:.2f}\\033[00m\" if acc1 > 90 else f\"{acc1:.2f}\"\n",
+    "print(\"Bagged Trees Accuracy for sensor 1:\", acc1)\n",
+    "bagged_model2 = BaggingClassifier(estimator=DecisionTreeClassifier(), n_estimators=10)\n",
+    "bagged_model2.fit(x_train2, y_train)\n",
+    "bagged_pred2 = bagged_model2.predict(x_test2)\n",
+    "acc2 = accuracy_score(y_test, bagged_pred2) * 100\n",
+    "accuracies2.append(acc2)\n",
+    "# format with color coded if acc2 > 90\n",
+    "acc2 = f\"\\033[92m{acc2:.2f}\\033[00m\" if acc2 > 90 else f\"{acc2:.2f}\"\n",
+    "print(\"Bagged Trees Accuracy for sensor 2:\", acc2)\n",
+    "\n",
+    "# 3. Decision Tree\n",
+    "dt_model = DecisionTreeClassifier()\n",
+    "dt_model.fit(x_train1, y_train)\n",
+    "dt_pred1 = dt_model.predict(x_test1)\n",
+    "acc1 = accuracy_score(y_test, dt_pred1) * 100\n",
+    "accuracies1.append(acc1)\n",
+    "# format with color coded if acc1 > 90\n",
+    "acc1 = f\"\\033[92m{acc1:.2f}\\033[00m\" if acc1 > 90 else f\"{acc1:.2f}\"\n",
+    "print(\"Decision Tree Accuracy for sensor 1:\", acc1)\n",
+    "dt_model2 = DecisionTreeClassifier()\n",
+    "dt_model2.fit(x_train2, y_train)\n",
+    "dt_pred2 = dt_model2.predict(x_test2)\n",
+    "acc2 = accuracy_score(y_test, dt_pred2) * 100\n",
+    "accuracies2.append(acc2)\n",
+    "# format with color coded if acc2 > 90\n",
+    "acc2 = f\"\\033[92m{acc2:.2f}\\033[00m\" if acc2 > 90 else f\"{acc2:.2f}\"\n",
+    "print(\"Decision Tree Accuracy for sensor 2:\", acc2)\n",
+    "\n",
+    "# 4. KNeighbors\n",
+    "knn_model = KNeighborsClassifier()\n",
+    "knn_model.fit(x_train1, y_train)\n",
+    "knn_pred1 = knn_model.predict(x_test1)\n",
+    "acc1 = accuracy_score(y_test, knn_pred1) * 100\n",
+    "accuracies1.append(acc1)\n",
+    "# format with color coded if acc1 > 90\n",
+    "acc1 = f\"\\033[92m{acc1:.2f}\\033[00m\" if acc1 > 90 else f\"{acc1:.2f}\"\n",
+    "print(\"KNeighbors Accuracy for sensor 1:\", acc1)\n",
+    "knn_model2 = KNeighborsClassifier()\n",
+    "knn_model2.fit(x_train2, y_train)\n",
+    "knn_pred2 = knn_model2.predict(x_test2)\n",
+    "acc2 = accuracy_score(y_test, knn_pred2) * 100\n",
+    "accuracies2.append(acc2)\n",
+    "# format with color coded if acc2 > 90\n",
+    "acc2 = f\"\\033[92m{acc2:.2f}\\033[00m\" if acc2 > 90 else f\"{acc2:.2f}\"\n",
+    "print(\"KNeighbors Accuracy for sensor 2:\", acc2)\n",
+    "\n",
+    "# 5. Linear Discriminant Analysis\n",
+    "lda_model = LinearDiscriminantAnalysis()\n",
+    "lda_model.fit(x_train1, y_train)\n",
+    "lda_pred1 = lda_model.predict(x_test1)\n",
+    "acc1 = accuracy_score(y_test, lda_pred1) * 100\n",
+    "accuracies1.append(acc1)\n",
+    "# format with color coded if acc1 > 90\n",
+    "acc1 = f\"\\033[92m{acc1:.2f}\\033[00m\" if acc1 > 90 else f\"{acc1:.2f}\"\n",
+    "print(\"Linear Discriminant Analysis Accuracy for sensor 1:\", acc1)\n",
+    "lda_model2 = LinearDiscriminantAnalysis()\n",
+    "lda_model2.fit(x_train2, y_train)\n",
+    "lda_pred2 = lda_model2.predict(x_test2)\n",
+    "acc2 = accuracy_score(y_test, lda_pred2) * 100\n",
+    "accuracies2.append(acc2)\n",
+    "# format with color coded if acc2 > 90\n",
+    "acc2 = f\"\\033[92m{acc2:.2f}\\033[00m\" if acc2 > 90 else f\"{acc2:.2f}\"\n",
+    "print(\"Linear Discriminant Analysis Accuracy for sensor 2:\", acc2)\n",
+    "\n",
+    "# 6. Support Vector Machine\n",
+    "svm_model = SVC()\n",
+    "svm_model.fit(x_train1, y_train)\n",
+    "svm_pred1 = svm_model.predict(x_test1)\n",
+    "acc1 = accuracy_score(y_test, svm_pred1) * 100\n",
+    "accuracies1.append(acc1)\n",
+    "# format with color coded if acc1 > 90\n",
+    "acc1 = f\"\\033[92m{acc1:.2f}\\033[00m\" if acc1 > 90 else f\"{acc1:.2f}\"\n",
+    "print(\"Support Vector Machine Accuracy for sensor 1:\", acc1)\n",
+    "svm_model2 = SVC()\n",
+    "svm_model2.fit(x_train2, y_train)\n",
+    "svm_pred2 = svm_model2.predict(x_test2)\n",
+    "acc2 = accuracy_score(y_test, svm_pred2) * 100\n",
+    "accuracies2.append(acc2)\n",
+    "# format with color coded if acc2 > 90\n",
+    "acc2 = f\"\\033[92m{acc2:.2f}\\033[00m\" if acc2 > 90 else f\"{acc2:.2f}\"\n",
+    "print(\"Support Vector Machine Accuracy for sensor 2:\", acc2)\n",
+    "\n",
+    "# 7. XGBoost\n",
+    "xgboost_model = XGBClassifier()\n",
+    "xgboost_model.fit(x_train1, y_train)\n",
+    "xgboost_pred1 = xgboost_model.predict(x_test1)\n",
+    "acc1 = accuracy_score(y_test, xgboost_pred1) * 100\n",
+    "accuracies1.append(acc1)\n",
+    "# format with color coded if acc1 > 90\n",
+    "acc1 = f\"\\033[92m{acc1:.2f}\\033[00m\" if acc1 > 90 else f\"{acc1:.2f}\"\n",
+    "print(\"XGBoost Accuracy:\", acc1)\n",
+    "xgboost_model2 = XGBClassifier()\n",
+    "xgboost_model2.fit(x_train2, y_train)\n",
+    "xgboost_pred2 = xgboost_model2.predict(x_test2)\n",
+    "acc2 = accuracy_score(y_test, xgboost_pred2) * 100\n",
+    "accuracies2.append(acc2)\n",
+    "# format with color coded if acc2 > 90\n",
+    "acc2 = f\"\\033[92m{acc2:.2f}\\033[00m\" if acc2 > 90 else f\"{acc2:.2f}\"\n",
+    "print(\"XGBoost Accuracy:\", acc2)"
    ]
   },
   {
@@ -714,35 +758,8 @@
    "metadata": {},
    "outputs": [],
    "source": [
-    "models_sensor2 = {\n",
-    "    # \"Random Forest\": RandomForestClassifier(),\n",
-    "    # \"Bagged Trees\": BaggingClassifier(estimator=DecisionTreeClassifier(), n_estimators=10),\n",
-    "    # \"Decision Tree\": DecisionTreeClassifier(),\n",
-    "    # \"KNN\": KNeighborsClassifier(),\n",
-    "    # \"LDA\": LinearDiscriminantAnalysis(),\n",
-    "    \"SVM\": SVC(),\n",
-    "    # \"XGBoost\": XGBClassifier()\n",
-    "}\n",
-    "\n",
-    "results_sensor2 = []\n",
-    "for name, model in models_sensor2.items():\n",
-    "    res = train_and_evaluate_model(model, name, \"sensor2\", x_train2, y_train, x_test2, y_test, export='D:/thesis/models/sensor2')\n",
-    "    results_sensor2.append(res)\n",
-    "    print(f\"{name} on sensor2: Accuracy = {res['accuracy']:.2f}%\")\n"
-   ]
-  },
-  {
-   "cell_type": "code",
-   "execution_count": null,
-   "metadata": {},
-   "outputs": [],
-   "source": [
-    "all_results = {\n",
-    "    \"sensor1\": results_sensor1,\n",
-    "    \"sensor2\": results_sensor2\n",
-    "}\n",
-    "\n",
-    "print(all_results)"
+    "print(accuracies1)\n",
+    "print(accuracies2)"
    ]
   },
   {
@@ -754,48 +771,36 @@
     "import numpy as np\n",
     "import matplotlib.pyplot as plt\n",
     "\n",
-    "def prepare_plot_data(results_dict):\n",
-    "    # Gather unique model names\n",
-    "    models_set = {entry['model'] for sensor in results_dict.values() for entry in sensor}\n",
-    "    models = sorted(list(models_set))\n",
-    "    \n",
-    "    # Create dictionaries mapping sensor -> accuracy list ordered by model name\n",
-    "    sensor_accuracies = {}\n",
-    "    for sensor, entries in results_dict.items():\n",
-    "        # Build a mapping: model -> accuracy for the given sensor\n",
-    "        mapping = {entry['model']: entry['accuracy'] for entry in entries}\n",
-    "        # Order the accuracies consistent with the sorted model names\n",
-    "        sensor_accuracies[sensor] = [mapping.get(model, 0) for model in models]\n",
-    "    \n",
-    "    return models, sensor_accuracies\n",
+    "models = [rf_model, bagged_model, dt_model, knn_model, lda_model, svm_model, xgboost_model]\n",
+    "model_names = [\"Random Forest\", \"Bagged Trees\", \"Decision Tree\", \"KNN\", \"LDA\", \"SVM\", \"XGBoost\"]\n",
     "\n",
-    "def plot_accuracies(models, sensor_accuracies):\n",
-    "    bar_width = 0.35\n",
-    "    x = np.arange(len(models))\n",
-    "    sensors = list(sensor_accuracies.keys())\n",
-    "    \n",
-    "    plt.figure(figsize=(10, 6))\n",
-    "    # Assume two sensors for plotting grouped bars\n",
-    "    plt.bar(x - bar_width/2, sensor_accuracies[sensors[0]], width=bar_width, color='blue', label=sensors[0])\n",
-    "    plt.bar(x + bar_width/2, sensor_accuracies[sensors[1]], width=bar_width, color='orange', label=sensors[1])\n",
-    "    \n",
-    "    # Add text labels on top of bars\n",
-    "    for i, (a1, a2) in enumerate(zip(sensor_accuracies[sensors[0]], sensor_accuracies[sensors[1]])):\n",
-    "        plt.text(x[i] - bar_width/2, a1 + 0.1, f\"{a1:.2f}%\", ha='center', va='bottom', color='black')\n",
-    "        plt.text(x[i] + bar_width/2, a2 + 0.1, f\"{a2:.2f}%\", ha='center', va='bottom', color='black')\n",
-    "    \n",
-    "    plt.xlabel('Model Name')\n",
-    "    plt.ylabel('Accuracy (%)')\n",
-    "    plt.title('Accuracy of Classifiers for Each Sensor')\n",
-    "    plt.xticks(x, models)\n",
-    "    plt.legend()\n",
-    "    plt.ylim(0, 105)\n",
-    "    plt.tight_layout()\n",
-    "    plt.show()\n",
+    "bar_width = 0.35  # Width of each bar\n",
+    "index = np.arange(len(model_names))  # Index for the bars\n",
     "\n",
-    "# Use the functions\n",
-    "models, sensor_accuracies = prepare_plot_data(all_results)\n",
-    "plot_accuracies(models, sensor_accuracies)\n"
+    "# Plotting the bar graph\n",
+    "plt.figure(figsize=(14, 8))\n",
+    "\n",
+    "# Bar plot for Sensor 1\n",
+    "plt.bar(index, accuracies1, width=bar_width, color='blue', label='Sensor 1')\n",
+    "\n",
+    "# Bar plot for Sensor 2\n",
+    "plt.bar(index + bar_width, accuracies2, width=bar_width, color='orange', label='Sensor 2')\n",
+    "\n",
+    "# Add values on top of each bar\n",
+    "for i, acc1, acc2 in zip(index, accuracies1, accuracies2):\n",
+    "    plt.text(i, acc1 + .1, f'{acc1:.2f}%', ha='center', va='bottom', color='black')\n",
+    "    plt.text(i + bar_width, acc2 + 1, f'{acc2:.2f}%', ha='center', va='bottom', color='black')\n",
+    "\n",
+    "# Customize the plot\n",
+    "plt.xlabel('Model Name →')\n",
+    "plt.ylabel('Accuracy →')\n",
+    "plt.title('Accuracy of classifiers for Sensors 1 and 2 with 513 features')\n",
+    "plt.xticks(index + bar_width / 2, model_names)  # Set x-tick positions\n",
+    "plt.legend()\n",
+    "plt.ylim(0, 100)\n",
+    "\n",
+    "# Show the plot\n",
+    "plt.show()\n"
    ]
   },
   {
@@ -839,8 +844,6 @@
    "source": [
     "from sklearn.metrics import accuracy_score, classification_report\n",
     "# 4. Validate on Dataset B\n",
-    "from joblib import load\n",
-    "svm_model = load('D:/thesis/models/sensor1/SVM.joblib')\n",
     "y_pred_svm = svm_model.predict(X1b)\n",
     "\n",
     "# 5. Evaluate\n",
@@ -848,30 +851,6 @@
     "print(classification_report(y, y_pred_svm))"
    ]
   },
-  {
-   "cell_type": "markdown",
-   "metadata": {},
-   "source": [
-    "### Model sensor 1 to predict sensor 2 data"
-   ]
-  },
-  {
-   "cell_type": "code",
-   "execution_count": null,
-   "metadata": {},
-   "outputs": [],
-   "source": [
-    "from sklearn.metrics import accuracy_score, classification_report\n",
-    "# 4. Validate on Dataset B\n",
-    "from joblib import load\n",
-    "svm_model = load('D:/thesis/models/sensor1/SVM.joblib')\n",
-    "y_pred_svm = svm_model.predict(X2b)\n",
-    "\n",
-    "# 5. Evaluate\n",
-    "print(\"Accuracy on Dataset B:\", accuracy_score(y, y_pred_svm))\n",
-    "print(classification_report(y, y_pred_svm))"
-   ]
-  },
   {
    "cell_type": "code",
    "execution_count": null,
@@ -931,7 +910,7 @@
     "# Plot\n",
     "disp = ConfusionMatrixDisplay(confusion_matrix=cm, display_labels=labels)\n",
     "disp.plot(cmap=plt.cm.Blues)  # You can change colormap\n",
-    "plt.title(\"SVM Sensor1 CM Train w/ Dataset A Val w/ Dataset B from Sensor2 readings\")\n",
+    "plt.title(\"SVM Sensor1 CM Train w/ Dataset A Val w/ Dataset B\")\n",
     "plt.show()"
    ]
   },
@@ -949,14 +928,14 @@
    "outputs": [],
    "source": [
     "# 1. Predict sensor 1 on Dataset A\n",
-    "y_test_pred = svm_model.predict(x_test1)\n",
+    "y_train_pred = svm_model.predict(x_train1)\n",
     "\n",
     "# 2. Import confusion matrix tools\n",
     "from sklearn.metrics import confusion_matrix, ConfusionMatrixDisplay\n",
     "import matplotlib.pyplot as plt\n",
     "\n",
     "# 3. Create and plot confusion matrix\n",
-    "cm_train = confusion_matrix(y_test, y_test_pred)\n",
+    "cm_train = confusion_matrix(y_train, y_train_pred)\n",
     "labels = svm_model.classes_\n",
     "\n",
     "disp = ConfusionMatrixDisplay(confusion_matrix=cm_train, display_labels=labels)\n",

code/src/ml/model_selection.py

@@ -55,101 +55,3 @@ def create_ready_data(
         y = np.array([])
 
     return X, y
-
-
-def train_and_evaluate_model(
-    model, model_name, sensor_label, x_train, y_train, x_test, y_test, export=None
-):
-    """
-    Train a machine learning model, evaluate its performance, and optionally export it.
-
-    This function trains the provided model on the training data, evaluates its
-    performance on test data using accuracy score, and can save the trained model
-    to disk if an export path is provided.
-
-    Parameters
-    ----------
-    model : estimator object
-        The machine learning model to train.
-    model_name : str
-        Name of the model, used for the export filename and in the returned results.
-    sensor_label : str
-        Label identifying which sensor's data the model is being trained on.
-    x_train : array-like or pandas.DataFrame
-        The training input samples.
-    y_train : array-like
-        The target values for training.
-    x_test : array-like or pandas.DataFrame
-        The test input samples.
-    y_test : array-like
-        The target values for testing.
-    export : str, optional
-        Directory path where the trained model should be saved. If None, model won't be saved.
-
-    Returns
-    -------
-    dict
-        Dictionary containing:
-        - 'model': model_name (str)
-        - 'sensor': sensor_label (str)
-        - 'accuracy': accuracy percentage (float)
-
-    Example
-    -------
-    >>> from sklearn.svm import SVC
-    >>> from sklearn.model_selection import train_test_split
-    >>> X_train, X_test, y_train, y_test = train_test_split(features, labels, test_size=0.2)
-    >>> result = train_and_evaluate_model(
-    ...     SVC(),
-    ...     "SVM",
-    ...     "sensor1",
-    ...     X_train,
-    ...     y_train,
-    ...     X_test,
-    ...     y_test,
-    ...     export="models/sensor1"
-    ... )
-    >>> print(f"Model accuracy: {result['accuracy']:.2f}%")
-    """
-    from sklearn.metrics import accuracy_score
-
-    result = {"model": model_name, "sensor": sensor_label, "success": False}
-
-    try:
-        # Train the model
-        model.fit(x_train, y_train)
-
-        try:
-            y_pred = model.predict(x_test)
-        except Exception as e:
-            result["error"] = f"Prediction error: {str(e)}"
-            return result
-
-        # Calculate accuracy
-        try:
-            accuracy = accuracy_score(y_test, y_pred) * 100
-            result["accuracy"] = accuracy
-        except Exception as e:
-            result["error"] = f"Accuracy calculation error: {str(e)}"
-            return result
-
-        # Export model if requested
-        if export:
-            try:
-                import joblib
-
-                full_path = os.path.join(export, f"{model_name}.joblib")
-                os.makedirs(os.path.dirname(full_path), exist_ok=True)
-                joblib.dump(model, full_path)
-                print(f"Model saved to {full_path}")
-            except Exception as e:
-                print(f"Warning: Failed to export model to {export}: {str(e)}")
-                result["export_error"] = str(e)
-                # Continue despite export error
-
-        result["success"] = True
-        return result
-
-    except Exception as e:
-        result["error"] = f"Training error: {str(e)}"
-        return result

latex/chapters/id/03_methodology/steps/index.tex

@@ -3,7 +3,7 @@ Alur keseluruhan penelitian ini dilakukan melalui tahapan-tahapan sebagai beriku
 
 \begin{figure}[H]
     \centering
-    \includegraphics[width=0.3\linewidth]{chapters/img/flow.png}
+    \includegraphics[width=0.3\linewidth]{chapters/id/flow.png}
     \caption{Diagram alir tahapan penelitian}
     \label{fig:flowchart}
 \end{figure}

latex/frontmatter/glossaries.tex

@@ -1,78 +0,0 @@
-% % A new command that enables us to enter bi-lingual (Slovene and English) terms
-% % syntax: \addterm[options]{label}{Slovene}{Slovene first use}{English}{Slovene
-% % description}
-% \newcommand{\addterm}[6][]{
-%   \newglossaryentry{#2}{
-%     name={#3 (angl.\ #5)},
-%     first={#4 (\emph{#5})},
-%     text={#3},
-%     sort={#3},
-%     description={#6},
-%     #1 % pass additional options to \newglossaryentry
-%   }
-% }
-
-% % A new command that enables us to enter (English) acronyms with bi-lingual
-% % (Slovene and English) long versions
-% % syntax: \addacronym[options]{label}{abbreviation}{Slovene long}{Slovene first
-% % use long}{English long}{Slovene description}
-% \newcommand{\addacronym}[7][]{
-%   % Create the main glossary entry with \newacronym
-%   % \newacronym[key-val list]{label}{abbrv}{long}
-%   \newacronym[
-%     name={#4 (angl.\ #6,\ #3)},
-%     first={\emph{#5} (angl.\ \emph{#6},\ \emph{#3})},
-%     sort={#4},
-%     description={#7},
-%     #1 % pass additional options to \newglossaryentry
-%     ]
-%     {#2}{#3}{#4}
-%   % Create a cross-reference from the abbreviation to the main glossary entry by
-%   % creating an auxiliary glossary entry (note: we set the label of this entry
-%   % to '<original label>_auxiliary' to avoid clashes)
-%   \newglossaryentry{#2_auxiliary}{
-%     name={#3},
-%     sort={#3},
-%     description={\makefirstuc{#6}},
-%     see=[See:]{#2}
-%   }
-% }
-
-% % Change the text of the cross-reference links to the Slovene long version.
-% \renewcommand*{\glsseeitemformat}[1]{\emph{\acrlong{#1}}.}
-
-% Define the Indonesian term and link it to the English term
-\newglossaryentry{jaringansaraf}{
-  name=Jaringan Saraf,
-  description={The Indonesian term for \gls{nn}}
-}
-% \newglossaryentry{pemelajaranmesin}{
-%   name=Pemelajaran Mesin,
-%   description={Lihat \gls{machinelearning}}
-% }
-
-% Define the English term and link it to its acronym
-\newglossaryentry{neuralnetwork}{
-  name=Neural Network,
-  description={A computational model inspired by the human brain, see \gls{nn}}
-}
-
-% \newglossaryentry{machinelearning}{
-%   name=Machine Learning,
-%   description={A program or system that trains a model from input data. The trained model can make useful predictions from new (never-before-seen) data drawn from the same distribution as the one used to train the model.}}
-% \newglossaryentry{pemelajaranmesin}{
-%     name={pemelajaran mesin (angl.\ #5)},
-%     first={pemelajaran mesin (\emph{machine learning})},
-%     text={pemelajaran mesin},
-%     sort={ },
-%     description={#6},
-%     #1 % pass additional options to \newglossaryentry
-% }
-\longnewglossaryentry{machinelearning}{name={machine learning}}
-{A program or system that trains a model from input data. The trained model can make useful predictions from new (never-before-seen) data drawn from the same distribution as the one used to train the model.}
-\newterm[see={machinelearning}]{pemelajaranmesin}
-% \newglossaryentry{pemelajaran mesin}{}
-% \addterm{machinelearning}{pemelajaran mesin}{pemelajaran mesin}{machine learning}{A program or system that trains a model from input data. The trained model can make useful predictions from new (never-before-seen) data drawn from the same distribution as the one used to train the model.}
-\newacronym
- [description={statistical pattern recognition technique}]
- {svm}{SVM}{support vector machine}

latex/main.tex

@@ -1,18 +1,14 @@
 \documentclass[draftmark]{thesis}
 
-% Metadata
-\title{Prediksi Lokasi Kerusakan dengan Machine Learning}
-\author{Rifqi Damar Panuluh}
-\date{\today}
-\authorid{20210110224}
-\firstadvisor{Ir. Muhammad Ibnu Syamsi, Ph.D.}
-\secondadvisor{}
-\headdepartement{Puji Harsanto, S.T., M.T., Ph.D.}
-\headdepartementid{19740607201404123064}
-\faculty{Fakultas Teknik}
-\program{Program Studi Teknik Sipil}
-\university{Universitas Muhammadiyah Yogyakarta}
-\yearofsubmission{2025}
+% Title Information
+\setthesisinfo
+  {Prediksi Lokasi Kerusakan dengan Machine Learning}
+  {Rifqi Damar Panuluh}
+  {20210110224}
+  {PROGRAM STUDI TEKNIK SIPIL}
+  {FAKULTAS TEKNIK}
+  {UNIVERSITAS MUHAMMADIYAH YOGYAKARTA}
+  {2025}
 
 % Input preamble
 \input{preamble/packages}
@@ -20,19 +16,22 @@
 \input{preamble/macros}
 
 \begin{document}
-% \input{frontmatter/maketitle}
-% \input{frontmatter/maketitle_secondary}
+
+\maketitle
 \frontmatter
-% \input{frontmatter/approval}\clearpage
-% \input{frontmatter/originality}\clearpage
-% \input{frontmatter/acknowledgement}\clearpage
-% \tableofcontents
+\input{frontmatter/approval}\clearpage
+\input{frontmatter/originality}\clearpage
+\input{frontmatter/acknowledgement}\clearpage
+\tableofcontents
 \clearpage
 \mainmatter
 \pagestyle{fancyplain}
+% Include content
+\include{content/abstract}
+\include{content/introduction}
 \include{chapters/01_introduction}
-\include{chapters/id/02_literature_review/index}
-\include{chapters/id/03_methodology/index}
+\include{content/chapter2}
+\include{content/conclusion}
 
 % Bibliography
 % \bibliographystyle{IEEEtran}

latex/metadata.tex

@@ -0,0 +1,11 @@
+\newcommand{\studentname}{Rifqi Damar Panuluh}
+\newcommand{\studentid}{20210110224}
+\newcommand{\thesistitle}{Prediksi Lokasi Kerusakan dengan Machine Learning}
+\newcommand{\firstadvisor}{Ir. Muhammad Ibnu Syamsi, Ph.D.}
+\newcommand{\secondadvisor}{}
+\newcommand{\headdepartement}{Puji Harsanto, S.T. M.T., Ph.D.}
+\newcommand{\headdepartementid}{19740607201404123064}
+\newcommand{\faculty}{Fakultas Teknik}
+\newcommand{\program}{Teknik Sipil}
+\newcommand{\university}{Universitas Muhammadiyah Yogyakarta}
+\newcommand{\yearofsubmission}{2025}

latex/thesis.cls

@@ -1,7 +1,7 @@
 \NeedsTeXFormat{LaTeX2e}
 \ProvidesClass{thesis}[2025/05/10 Bachelor Thesis Class]
 
-\newif\if@draftmark \@draftmarkfalse
+\newif\if@draftmark
 \@draftmarkfalse
 
 \DeclareOption{draftmark}{\@draftmarktrue}
@@ -12,7 +12,6 @@
 \RequirePackage{polyglossia}
 \RequirePackage{fontspec}
 \RequirePackage{titlesec}
-\RequirePackage{titling}
 \RequirePackage{fancyhdr}
 \RequirePackage{geometry}
 \RequirePackage{setspace}
@@ -25,31 +24,30 @@
 \RequirePackage{svg}           % Allows including SVG images directly
 \RequirePackage{indentfirst}   % Makes first paragraph after headings indented
 \RequirePackage{float}         % Provides [H] option to force figure/table placement
-\RequirePackage[style=apa, backend=biber]{biblatex}
-\RequirePackage[acronym, nogroupskip, toc]{glossaries}
+
 % Polyglossia set language
-\setdefaultlanguage[variant=indonesian]{malay}  % Proper Indonesian language setup
-\setotherlanguage{english}             % Enables English as secondary language
-\DefineBibliographyStrings{english}{%  % Customizes bibliography text
-  andothers={dkk\adddot},              % Changes "et al." to "dkk."
-  pages={hlm\adddot},                  % Changes "pp." to "hlm."
-}
++ \setdefaultlanguage[variant=indonesian]{malay}  % Proper Indonesian language setup
++ \setotherlanguage{english}             % Enables English as secondary language
+
++ \DefineBibliographyStrings{english}{%  % Customizes bibliography text
++   andothers={dkk\adddot},              % Changes "et al." to "dkk."
++   pages={hlm\adddot},                  % Changes "pp." to "hlm."
++ }
 
 % Conditionally load the watermark package and settings
 \if@draftmark
   \RequirePackage{draftwatermark}
-  \SetWatermarkText{nuluh/thesis (wip) [draft: \today]}
+  \SetWatermarkText{nuluh/thesis (wip) draft: \today}
   \SetWatermarkColor[gray]{0.8}                    % Opacity: 0.8 = 20% transparent  
   \SetWatermarkFontSize{1.5cm}
   \SetWatermarkAngle{90}
   \SetWatermarkHorCenter{1.5cm}
-  \RequirePackage[left]{lineno}
-  \linenumbers
 \fi
 
 % Page layout
-\geometry{left=4cm, top=3cm, right=3cm, bottom=3cm}
+\geometry{left=3cm, top=3cm, right=3cm, bottom=3cm}
 \setlength{\parskip}{0.5em}
+\setlength{\parindent}{0pt}
 \onehalfspacing
 
 % Fonts
@@ -58,45 +56,19 @@
 \setsansfont{Arial}
 \setmonofont{Courier New}
 
-\makeatletter
-% Extracting the Year from \today
-\newcommand{\theyear}{%
-  \expandafter\@car\expandafter\@gobble\the\year\@nil
+% Metadata commands
+\input{metadata}
+
+\newcommand{\setthesisinfo}[7]{%
+  \renewcommand{\thesistitle}{#1}%
+  \renewcommand{\studentname}{#2}%
+  \renewcommand{\studentid}{#3}%
+  \renewcommand{\program}{#4}%
+  \renewcommand{\faculty}{#5}%
+  \renewcommand{\university}{#6}%
+  \renewcommand{\yearofsubmission}{#7}%
 }
 
-% Declare internal macros as initially empty
-\newcommand{\@authorid}{}
-\newcommand{\@firstadvisor}{}
-\newcommand{\@secondadvisor}{}
-\newcommand{\@headdepartement}{}
-\newcommand{\@headdepartementid}{}
-\newcommand{\@faculty}{}
-\newcommand{\@program}{}
-\newcommand{\@university}{}
-\newcommand{\@yearofsubmission}{}
-
-% Define user commands to set these values.
-\newcommand{\authorid}[1]{\gdef\@authorid{#1}}
-\newcommand{\firstadvisor}[1]{\gdef\@firstadvisor{#1}}
-\newcommand{\secondadvisor}[1]{\gdef\@secondadvisor{#1}}
-\newcommand{\headdepartement}[1]{\gdef\@headdepartement{#1}}
-\newcommand{\headdepartementid}[1]{\gdef\@headdepartementid{#1}}
-\newcommand{\faculty}[1]{\gdef\@faculty{#1}}
-\newcommand{\program}[1]{\gdef\@program{#1}}
-\newcommand{\university}[1]{\gdef\@university{#1}}
-\newcommand{\yearofsubmission}[1]{\gdef\@yearofsubmission{#1}}
-
-% Now expose robust “the‑” getters to access the values
-\newcommand{\theauthorid}{\@authorid}
-\newcommand{\thefirstadvisor}{\@firstadvisor}
-\newcommand{\thesecondadvisor}{\@secondadvisor}
-\newcommand{\theheaddepartement}{\@headdepartement}
-\newcommand{\theheaddepartementid}{\@headdepartementid}
-\newcommand{\thefaculty}{\@faculty}
-\newcommand{\theprogram}{\@program}
-\newcommand{\theuniversity}{\@university}
-\newcommand{\theyearofsubmission}{\@yearofsubmission}
-\makeatother
 % % Header and footer
 \fancypagestyle{fancy}{%
     \fancyhf{}
@@ -138,6 +110,11 @@
 \renewcommand{\cftchappresnum}{BAB~}
 \renewcommand{\cftchapaftersnum}{\quad}
 
+% \titlespacing*{\chapter}{0pt}{-10pt}{20pt}
+
+% Redefine \maketitle
+\renewcommand{\maketitle}{\input{frontmatter/maketitle}}
+
 % Chapter & Section format
 \renewcommand{\cftchapfont}{\normalsize\MakeUppercase}
 % \renewcommand{\cftsecfont}{}
@@ -159,15 +136,11 @@
 \setlength{\cftsubsecnumwidth}{2.5em}
 \setlength{\cftfignumwidth}{5em}
 \setlength{\cfttabnumwidth}{4em}
-\renewcommand \cftchapdotsep{1} % https://tex.stackexchange.com/a/273764
-\renewcommand \cftsecdotsep{1} % https://tex.stackexchange.com/a/273764
-\renewcommand \cftsubsecdotsep{1} % https://tex.stackexchange.com/a/273764
-\renewcommand \cftfigdotsep{1.5} % https://tex.stackexchange.com/a/273764
-\renewcommand \cfttabdotsep{1.5} % https://tex.stackexchange.com/a/273764
+\renewcommand \cftchapdotsep{1}           % Denser dots (closer together) https://tex.stackexchange.com/a/273764
+\renewcommand \cftsecdotsep{1}            % Apply to sections too
+\renewcommand \cftsubsecdotsep{1}         % Apply to subsections too
 \renewcommand{\cftchapleader}{\normalfont\cftdotfill{\cftsecdotsep}}
 \renewcommand{\cftchappagefont}{\normalfont}
-
-% Add Prefix in the Lof and LoT entries
 \renewcommand{\cftfigpresnum}{\figurename~}
 \renewcommand{\cfttabpresnum}{\tablename~}
 
@@ -192,147 +165,6 @@
 % \renewcommand{\cfttoctitlefont}{\bfseries\MakeUppercase}
 % \renewcommand{\cftaftertoctitle}{\vskip 2em}
 
-% Defines a new glossary called “notation”
-\newglossary[nlg]{notation}{not}{ntn}{Notation}
-
-% Define the header for the location column
-\providecommand*{\locationname}{Location}
-
-% Define the new glossary style called 'mylistalt' for main glossaries
-\makeatletter
-\newglossarystyle{mylistalt}{%
-  % start the list, initializing glossaries internals
-  \renewenvironment{theglossary}%
-    {\glslistinit\begin{enumerate}}%
-    {\end{enumerate}}%
-  % suppress all headers/groupskips
-  \renewcommand*{\glossaryheader}{}%
-  \renewcommand*{\glsgroupheading}[1]{}%
-  \renewcommand*{\glsgroupskip}{}%
-  % main entries: let \item produce "1." etc., then break
-  \renewcommand*{\glossentry}[2]{%
-    \item \glstarget{##1}{\glossentryname{##1}}%
-    \mbox{}\\
-    \glossentrydesc{##1}\space 
-    [##2] % appears on page x
-  }%
-  % sub-entries as separate paragraphs, still aligned
-  \renewcommand*{\subglossentry}[3]{%
-    \par
-    \glssubentryitem{##2}%
-    \glstarget{##2}{\strut}\space
-    \glossentrydesc{##2}\space ##3%
-  }%
-}
-
-
-% Define the new glossary style 'altlong3customheader' for notation
-\newglossarystyle{altlong3customheader}{%
-  % The glossary will be a longtable environment with three columns:
-  % 1. Symbol (left-aligned)
-  % 2. Description (paragraph, width \glsdescwidth)
-  % 3. Location (paragraph, width \glspagelistwidth)
-  \renewenvironment{theglossary}%
-    {\begin{longtable}{lp{\glsdescwidth}p{\glspagelistwidth}}}%
-    {\end{longtable}}%
-  % Define the table header row
-  \renewcommand*{\symbolname}{Simbol}
-  \renewcommand*{\descriptionname}{Keterangan}
-  \renewcommand*{\locationname}{Halaman}
-  \renewcommand*{\glossaryheader}{%
-    \bfseries\symbolname & \bfseries\descriptionname & \bfseries\locationname \tabularnewline\endhead}%
-  % Suppress group headings (e.g., A, B, C...)
-  \renewcommand*{\glsgroupheading}[1]{}%
-  % Define how a main glossary entry is displayed
-  % ##1 is the entry label
-  % ##2 is the location list (page numbers)
-  \renewcommand{\glossentry}[2]{%
-    \glsentryitem{##1}% Inserts entry number if entrycounter option is used
-    \glstarget{##1}{\glossentryname{##1}} & % Column 1: Symbol (with hyperlink target)
-    \glossentrydesc{##1}\glspostdescription & % Column 2: Description (with post-description punctuation)
-    ##2\tabularnewline % Column 3: Location list
-  }%
-  % Define how a sub-entry is displayed
-  % ##1 is the sub-entry level (e.g., 1 for first sub-level)
-  % ##2 is the entry label
-  % ##3 is the location list
-  \renewcommand{\subglossentry}[3]{%
-    & % Column 1 (Symbol) is left blank for sub-entries to create an indented look
-    \glssubentryitem{##2}% Inserts sub-entry number if subentrycounter is used
-    \glstarget{##2}{\strut}\glossentrydesc{##2}\glspostdescription & % Column 2: Description (target on strut for hyperlink)
-    ##3\tabularnewline % Column 3: Location list
-  }%
-  % Define the skip between letter groups (if group headings were enabled)
-  % For 3 columns, we need 2 ampersands for a full blank row if not using \multicolumn
-  \ifglsnogroupskip
-    \renewcommand*{\glsgroupskip}{}%
-  \else
-    \renewcommand*{\glsgroupskip}{& & \tabularnewline}%
-  \fi
-}
-
-% Define a new style 'supercol' based on 'super' for acronyms glossaries
-\newglossarystyle{supercol}{%
-  \setglossarystyle{super}% inherit everything from the original
-  % override just the main-entry format:
-  \renewcommand*{\glossentry}[2]{%
-    \glsentryitem{##1}%
-    \glstarget{##1}{\glossentryname{##1}}\space  % <-- added colon here
-    &: \glossentrydesc{##1}\glspostdescription\space ##2\tabularnewline
-  }%
-  % likewise for sub‐entries, if you want a colon there too:
-  \renewcommand*{\subglossentry}[3]{%
-    &: 
-    \glssubentryitem{##2}%
-    \glstarget{##2}{\strut}\glossentryname{##2}\space % <-- and here
-    \glossentrydesc{##2}\glspostdescription\space ##3\tabularnewline
-  }%
-}
-\makeatother
-
-% A new command that enables us to enter bi-lingual (Bahasa Indonesia and English) terms
-% syntax: \addterm[options]{label}{Bahasa Indonesia}{Bahasa Indonesia first use}{English}{Bahasa Indonesia
-% description}
-\newcommand{\addterm}[6][]{
-  \newglossaryentry{#2}{
-    name={#3 (angl.\ #5)},
-    first={#4 (\emph{#5})},
-    text={#3},
-    sort={#3},
-    description={#6},
-    #1 % pass additional options to \newglossaryentry
-  }
-}
-
-% A new command that enables us to enter (English) acronyms with bi-lingual
-% (Bahasa Indonesia and English) long versions
-% syntax: \addacronym[options]{label}{abbreviation}{Bahasa Indonesia long}{Bahasa Indonesia first
-% use long}{English long}{Bahasa Indonesia description}
-\newcommand{\addacronym}[7][]{
-  % Create the main glossary entry with \newacronym
-  % \newacronym[key-val list]{label}{abbrv}{long}
-  \newacronym[
-    name={#4 (angl.\ #6,\ #3)},
-    first={\emph{#5} (angl.\ \emph{#6},\ \emph{#3})},
-    sort={#4},
-    description={#7},
-    #1 % pass additional options to \newglossaryentry
-    ]
-    {#2}{#3}{#4}
-  % Create a cross-reference from the abbreviation to the main glossary entry by
-  % creating an auxiliary glossary entry (note: we set the label of this entry
-  % to '<original label>_auxiliary' to avoid clashes)
-  \newglossaryentry{#2_auxiliary}{
-    name={#3},
-    sort={#3},
-    description={\makefirstuc{#6}},
-    see=[See:]{#2}
-  }
-}
-
-% Change the text of the cross-reference links to the Bahasa Indonesia long version.
-\renewcommand*{\glsseeitemformat}[1]{\emph{\acrlong{#1}}.}
-
 % % Apply a custom fancyhdr layout only on the first page of each \chapter, and use no header/footer elsewhere
 % % \let\oldchapter\chapter
 % % \renewcommand{\chapter}{%