Move Python package files to new package directories

Signed-off-by: Bobby Noelte <b0661n0e17e@gmail.com>

src/akkudoktoreos/visualize.py

@@ -0,0 +1,292 @@
+import datetime
+
+# Set the backend for matplotlib to Agg
+import matplotlib
+import matplotlib.pyplot as plt
+import numpy as np
+from matplotlib.backends.backend_pdf import PdfPages
+
+from modules.class_sommerzeit import ist_dst_wechsel
+
+matplotlib.use("Agg")
+
+
+def visualisiere_ergebnisse(
+    gesamtlast,
+    pv_forecast,
+    strompreise,
+    ergebnisse,
+    discharge_hours,
+    laden_moeglich,
+    temperature,
+    start_hour,
+    prediction_hours,
+    einspeiseverguetung_euro_pro_wh,
+    filename="visualization_results.pdf",
+    extra_data=None,
+):
+    #####################
+    # 24-hour visualization
+    #####################
+    with PdfPages(filename) as pdf:
+        # Load and PV generation
+        plt.figure(figsize=(14, 14))
+        plt.subplot(3, 3, 1)
+        hours = np.arange(0, prediction_hours)
+
+        gesamtlast_array = np.array(gesamtlast)
+        # Plot individual loads
+        plt.plot(hours, gesamtlast_array, label="Load (Wh)", marker="o")
+
+        # Calculate and plot total load
+        plt.plot(
+            hours,
+            gesamtlast_array,
+            label="Total Load (Wh)",
+            marker="o",
+            linewidth=2,
+            linestyle="--",
+        )
+        plt.xlabel("Hour")
+        plt.ylabel("Load (Wh)")
+        plt.title("Load Profiles")
+        plt.grid(True)
+        plt.legend()
+
+        # Electricity prices
+        hours_p = np.arange(0, len(strompreise))
+        plt.subplot(3, 2, 2)
+        plt.plot(
+            hours_p,
+            strompreise,
+            label="Electricity Price (€/Wh)",
+            color="purple",
+            marker="s",
+        )
+        plt.title("Electricity Prices")
+        plt.xlabel("Hour of the Day")
+        plt.ylabel("Price (€/Wh)")
+        plt.legend()
+        plt.grid(True)
+
+        # PV forecast
+        plt.subplot(3, 2, 3)
+        plt.plot(hours, pv_forecast, label="PV Generation (Wh)", marker="x")
+        plt.title("PV Forecast")
+        plt.xlabel("Hour of the Day")
+        plt.ylabel("Wh")
+        plt.legend()
+        plt.grid(True)
+
+        # Feed-in remuneration
+        plt.subplot(3, 2, 4)
+        plt.plot(
+            hours,
+            einspeiseverguetung_euro_pro_wh,
+            label="Remuneration (€/Wh)",
+            marker="x",
+        )
+        plt.title("Remuneration")
+        plt.xlabel("Hour of the Day")
+        plt.ylabel("€/Wh")
+        plt.legend()
+        plt.grid(True)
+
+        # Temperature forecast
+        plt.subplot(3, 2, 5)
+        plt.title("Temperature Forecast (°C)")
+        plt.plot(hours, temperature, label="Temperature (°C)", marker="x")
+        plt.xlabel("Hour of the Day")
+        plt.ylabel("°C")
+        plt.legend()
+        plt.grid(True)
+
+        pdf.savefig()  # Save the current figure state to the PDF
+        plt.close()  # Close the current figure to free up memory
+
+        #####################
+        # Start hour visualization
+        #####################
+
+        plt.figure(figsize=(14, 10))
+
+        if ist_dst_wechsel(datetime.datetime.now()):
+            hours = np.arange(start_hour, prediction_hours - 1)
+        else:
+            hours = np.arange(start_hour, prediction_hours)
+
+        # Energy flow, grid feed-in, and grid consumption
+        plt.subplot(3, 2, 1)
+        plt.plot(hours, ergebnisse["Last_Wh_pro_Stunde"], label="Load (Wh)", marker="o")
+        plt.plot(
+            hours,
+            ergebnisse["Haushaltsgeraet_wh_pro_stunde"],
+            label="Household Device (Wh)",
+            marker="o",
+        )
+        plt.plot(
+            hours,
+            ergebnisse["Netzeinspeisung_Wh_pro_Stunde"],
+            label="Grid Feed-in (Wh)",
+            marker="x",
+        )
+        plt.plot(
+            hours,
+            ergebnisse["Netzbezug_Wh_pro_Stunde"],
+            label="Grid Consumption (Wh)",
+            marker="^",
+        )
+        plt.plot(
+            hours, ergebnisse["Verluste_Pro_Stunde"], label="Losses (Wh)", marker="^"
+        )
+        plt.title("Energy Flow per Hour")
+        plt.xlabel("Hour")
+        plt.ylabel("Energy (Wh)")
+        plt.legend()
+
+        # State of charge for batteries
+        plt.subplot(3, 2, 2)
+        plt.plot(
+            hours, ergebnisse["akku_soc_pro_stunde"], label="PV Battery (%)", marker="x"
+        )
+        plt.plot(
+            hours,
+            ergebnisse["E-Auto_SoC_pro_Stunde"],
+            label="E-Car Battery (%)",
+            marker="x",
+        )
+        plt.legend(
+            loc="upper left", bbox_to_anchor=(1, 1)
+        )  # Place legend outside the plot
+        plt.grid(True, which="both", axis="x")  # Grid for every hour
+
+        ax1 = plt.subplot(3, 2, 3)
+        for hour, value in enumerate(discharge_hours):
+            ax1.axvspan(
+                hour,
+                hour + 1,
+                color="red",
+                ymax=value,
+                alpha=0.3,
+                label="Discharge Possibility" if hour == 0 else "",
+            )
+        for hour, value in enumerate(laden_moeglich):
+            ax1.axvspan(
+                hour,
+                hour + 1,
+                color="green",
+                ymax=value,
+                alpha=0.3,
+                label="Charging Possibility" if hour == 0 else "",
+            )
+        ax1.legend(loc="upper left")
+        ax1.set_xlim(0, prediction_hours)
+
+        pdf.savefig()  # Save the current figure state to the PDF
+        plt.close()  # Close the current figure to free up memory
+
+        # Financial overview
+        fig, axs = plt.subplots(1, 2, figsize=(14, 10))  # Create a 1x2 grid of subplots
+        total_costs = ergebnisse["Gesamtkosten_Euro"]
+        total_revenue = ergebnisse["Gesamteinnahmen_Euro"]
+        total_balance = ergebnisse["Gesamtbilanz_Euro"]
+        losses = ergebnisse["Gesamt_Verluste"]
+
+        # Costs and revenues per hour on the first axis (axs[0])
+        axs[0].plot(
+            hours,
+            ergebnisse["Kosten_Euro_pro_Stunde"],
+            label="Costs (Euro)",
+            marker="o",
+            color="red",
+        )
+        axs[0].plot(
+            hours,
+            ergebnisse["Einnahmen_Euro_pro_Stunde"],
+            label="Revenue (Euro)",
+            marker="x",
+            color="green",
+        )
+        axs[0].set_title("Financial Balance per Hour")
+        axs[0].set_xlabel("Hour")
+        axs[0].set_ylabel("Euro")
+        axs[0].legend()
+        axs[0].grid(True)
+
+        # Summary of finances on the second axis (axs[1])
+        labels = ["Total Costs [€]", "Total Revenue [€]", "Total Balance [€]"]
+        values = [total_costs, total_revenue, total_balance]
+        colors = ["red" if value > 0 else "green" for value in values]
+        axs[1].bar(labels, values, color=colors)
+        axs[1].set_title("Financial Overview")
+        axs[1].set_ylabel("Euro")
+
+        # Second axis (ax2) for losses, shared with axs[1]
+        ax2 = axs[1].twinx()
+        ax2.bar("Total Losses", losses, color="blue")
+        ax2.set_ylabel("Losses [Wh]", color="blue")
+        ax2.tick_params(axis="y", labelcolor="blue")
+
+        pdf.savefig()  # Save the complete figure to the PDF
+        plt.close()  # Close the figure
+
+        # Additional data visualization if provided
+        if extra_data is not None:
+            plt.figure(figsize=(14, 10))
+            plt.subplot(1, 2, 1)
+            f1 = np.array(extra_data["verluste"])
+            f2 = np.array(extra_data["bilanz"])
+            n1 = np.array(extra_data["nebenbedingung"])
+            scatter = plt.scatter(f1, f2, c=n1, cmap="viridis")
+
+            # Add color legend
+            plt.colorbar(scatter, label="Constraint")
+
+            pdf.savefig()  # Save the complete figure to the PDF
+            plt.close()  # Close the figure
+
+            plt.figure(figsize=(14, 10))
+            filtered_losses = np.array(
+                [
+                    v
+                    for v, n in zip(
+                        extra_data["verluste"], extra_data["nebenbedingung"]
+                    )
+                    if n < 0.01
+                ]
+            )
+            filtered_balance = np.array(
+                [
+                    b
+                    for b, n in zip(extra_data["bilanz"], extra_data["nebenbedingung"])
+                    if n < 0.01
+                ]
+            )
+            if filtered_losses.size != 0:
+                best_loss = min(filtered_losses)
+                worst_loss = max(filtered_losses)
+                best_balance = min(filtered_balance)
+                worst_balance = max(filtered_balance)
+
+                data = [filtered_losses, filtered_balance]
+                labels = ["Losses", "Balance"]
+                # Create plots
+                fig, axs = plt.subplots(
+                    1, 2, figsize=(10, 6), sharey=False
+                )  # Two subplots, separate y-axes
+
+                # First violin plot for losses
+                axs[0].violinplot(data[0], showmeans=True, showmedians=True)
+                axs[0].set_title("Losses")
+                axs[0].set_xticklabels(["Losses"])
+
+                # Second violin plot for balance
+                axs[1].violinplot(data[1], showmeans=True, showmedians=True)
+                axs[1].set_title("Balance")
+                axs[1].set_xticklabels(["Balance"])
+
+                # Fine-tuning
+                plt.tight_layout()
+
+            pdf.savefig()  # Save the current figure state to the PDF
+            plt.close()  # Close the figure