243 lines
10 KiB
Python
243 lines
10 KiB
Python
# target_simulator/gui/ppi_display.py
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"""
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A reusable Tkinter widget that displays a Plan Position Indicator (PPI)
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using Matplotlib, capable of showing both live targets and trajectory previews.
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"""
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import tkinter as tk
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from tkinter import ttk
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import math
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import numpy as np
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import copy
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from matplotlib.figure import Figure
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from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
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# Use absolute imports
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from target_simulator.core.models import Target, Waypoint, ManeuverType
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from typing import List, Optional
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class PPIDisplay(ttk.Frame):
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"""A custom, reusable widget for the PPI radar display."""
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def __init__(self, master, max_range_nm: int = 100, scan_limit_deg: int = 60):
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super().__init__(master)
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self.max_range = max_range_nm
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self.scan_limit_deg = scan_limit_deg
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self.target_artists = []
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self.active_targets: List[Target] = []
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self._target_dots = []
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self.preview_artists = []
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self._create_controls()
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self._create_plot()
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def _create_controls(self):
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"""Creates the control widgets for the PPI display."""
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self.controls_frame = ttk.Frame(self)
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self.controls_frame.pack(side=tk.TOP, fill=tk.X, padx=5, pady=5)
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ttk.Label(self.controls_frame, text="Range (NM):").pack(side=tk.LEFT)
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# Create a list of valid range steps up to the theoretical max_range
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all_steps = [10, 20, 40, 80, 100, 160]
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valid_steps = sorted([s for s in all_steps if s <= self.max_range])
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if not valid_steps:
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valid_steps = [self.max_range]
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# Ensure the initial max range is in the list if not a standard step
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if self.max_range not in valid_steps:
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valid_steps.append(self.max_range)
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valid_steps.sort()
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# The initial value for the combobox is the max_range passed to the constructor
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self.range_var = tk.IntVar(value=self.max_range)
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self.range_selector = ttk.Combobox(
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self.controls_frame, textvariable=self.range_var,
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values=valid_steps, state="readonly", width=5
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)
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self.range_selector.pack(side=tk.LEFT, padx=5)
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self.range_selector.bind("<<ComboboxSelected>>", self._on_range_selected)
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def _create_plot(self):
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"""Initializes the Matplotlib polar plot."""
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fig = Figure(figsize=(5, 5), dpi=100, facecolor='#3E3E3E')
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fig.subplots_adjust(left=0.05, right=0.95, top=0.85, bottom=0.05)
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self.ax = fig.add_subplot(111, projection='polar', facecolor='#2E2E2E')
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self.ax.set_theta_zero_location('N')
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self.ax.set_theta_direction(-1)
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self.ax.set_rlabel_position(90)
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self.ax.set_ylim(0, self.range_var.get())
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angles = np.arange(0, 360, 30)
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labels = [f"{angle}°" if angle == 0 else f"+{angle}°" if angle < 180 else "±180°" if angle == 180 else f"-{360 - angle}°" for angle in angles]
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self.ax.set_thetagrids(angles, labels)
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self.ax.tick_params(axis='x', colors='white', labelsize=8)
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self.ax.tick_params(axis='y', colors='white', labelsize=8)
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self.ax.grid(color='white', linestyle='--', linewidth=0.5, alpha=0.5)
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self.ax.spines['polar'].set_color('white')
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self.ax.set_title("PPI Display", color='white', y=1.08)
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# --- Artists for drawing ---
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self._start_plot, = self.ax.plot([], [], 'go', markersize=8)
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self._waypoints_plot, = self.ax.plot([], [], 'y+', markersize=10, mew=2, linestyle='None')
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self._path_plot, = self.ax.plot([], [], 'g--', linewidth=1.5)
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self.preview_artists = [self._start_plot, self._waypoints_plot, self._path_plot]
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# --- NEW: Create artists for scan lines ---
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limit_rad = np.deg2rad(self.scan_limit_deg)
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self._scan_line_1, = self.ax.plot([limit_rad, limit_rad], [0, self.max_range], color='yellow', linestyle='--', linewidth=1)
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self._scan_line_2, = self.ax.plot([-limit_rad, -limit_rad], [0, self.max_range], color='yellow', linestyle='--', linewidth=1)
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self._tooltip_label = None
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self.canvas = FigureCanvasTkAgg(fig, master=self)
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self.canvas.draw()
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self.canvas.get_tk_widget().pack(side=tk.TOP, fill=tk.BOTH, expand=True)
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self.canvas.mpl_connect('motion_notify_event', self._on_motion)
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# --- NEW: Initial draw of scan lines ---
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self._update_scan_lines()
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def _update_scan_lines(self):
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"""Updates the length of the scan sector lines to match the current range."""
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current_range_max = self.ax.get_ylim()[1]
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self._scan_line_1.set_ydata([0, current_range_max])
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self._scan_line_2.set_ydata([0, current_range_max])
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def _on_range_selected(self, event=None):
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"""Handles the selection of a new range."""
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new_range = self.range_var.get()
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self.ax.set_ylim(0, new_range)
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# --- NEW: Update scan lines on zoom change ---
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self._update_scan_lines()
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self.update_targets(self.active_targets)
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self.canvas.draw()
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# ... il resto dei metodi rimane invariato ...
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def update_targets(self, targets: List[Target]):
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# (This method is unchanged)
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self.active_targets = [t for t in targets if t.active]
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for artist in self.target_artists: artist.remove()
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self.target_artists.clear()
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self._target_dots.clear()
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vector_len = self.range_var.get() / 25
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for target in self.active_targets:
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r = target.current_range_nm
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theta = np.deg2rad(target.current_azimuth_deg)
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dot, = self.ax.plot(theta, r, 'o', markersize=5, color='red')
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self.target_artists.append(dot)
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self._target_dots.append((dot, target))
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x1, y1 = r * np.sin(theta), r * np.cos(theta)
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h_rad = np.deg2rad(target.current_heading_deg)
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dx, dy = vector_len * np.sin(h_rad), vector_len * np.cos(h_rad)
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x2, y2 = x1 + dx, y1 + dy
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r2, th2 = np.sqrt(x2**2 + y2**2), np.arctan2(x2, y2)
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line, = self.ax.plot([theta, th2], [r, r2], color='red', linewidth=1.2)
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self.target_artists.append(line)
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self.canvas.draw()
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def draw_trajectory_preview(self, waypoints: List[Waypoint]):
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"""Simulates and draws a trajectory preview.
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Args:
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waypoints: The full list of waypoints defining the trajectory.
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"""
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self.clear_previews()
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self._on_range_selected() # Ensure axis is synced with combobox
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if not waypoints or waypoints[0].maneuver_type != ManeuverType.FLY_TO_POINT:
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self.canvas.draw()
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return
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# --- LOGICA DI CREAZIONE DEL TARGET CORRETTA ---
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# Create a temporary target for simulation by passing only the trajectory.
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# The Target's __init__ and reset_simulation() will handle the initial state.
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temp_target = Target(target_id=0, trajectory=copy.deepcopy(waypoints))
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path_thetas, path_rs = [], []
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wp_thetas, wp_rs = [], []
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total_duration = sum(wp.duration_s for wp in waypoints if wp.duration_s is not None)
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sim_time, time_step = 0.0, 0.5
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path_thetas.append(math.radians(temp_target.current_azimuth_deg))
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path_rs.append(temp_target.current_range_nm)
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# Record waypoint positions for the plot markers
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for wp in waypoints:
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if wp.maneuver_type == ManeuverType.FLY_TO_POINT:
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wp_thetas.append(math.radians(wp.target_azimuth_deg))
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wp_rs.append(wp.target_range_nm)
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# Simulate path
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while sim_time < total_duration:
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temp_target.update_state(time_step)
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path_thetas.append(math.radians(temp_target.current_azimuth_deg))
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path_rs.append(temp_target.current_range_nm)
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sim_time += time_step
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start_r, start_theta = waypoints[0].target_range_nm, math.radians(waypoints[0].target_azimuth_deg)
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self._start_plot.set_data([start_theta], [start_r])
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self._waypoints_plot.set_data(wp_thetas, wp_rs)
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self._path_plot.set_data(path_thetas, path_rs)
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self._update_scan_lines()
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self.canvas.draw()
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def clear_previews(self):
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# (This method is unchanged)
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for artist in self.preview_artists: artist.set_data([], [])
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self.canvas.draw()
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def _on_motion(self, event):
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# (This method is unchanged)
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if event.inaxes != self.ax:
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if self._tooltip_label: self._tooltip_label.place_forget(); self._tooltip_label = None
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return
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found = False
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for dot, target in self._target_dots:
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cont, _ = dot.contains(event)
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if cont:
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self._show_tooltip(event.x + 10, event.y + 10, f"ID: {target.target_id}"); found = True; break
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if not found and self._tooltip_label: self._tooltip_label.place_forget(); self._tooltip_label = None
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def _show_tooltip(self, x, y, text):
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# (This method is unchanged)
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if self._tooltip_label: self._tooltip_label.place_forget()
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self._tooltip_label = tk.Label(self.canvas.get_tk_widget(), text=text, bg='yellow', fg='black', font=('Consolas', 9), relief='solid', borderwidth=1)
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self._tooltip_label.place(x=x, y=y)
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def reconfigure_radar(self, max_range_nm: int, scan_limit_deg: int):
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"""
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Updates the radar parameters (range, scan limit) of an existing PPI display.
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"""
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self.max_range = max_range_nm
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self.scan_limit_deg = scan_limit_deg
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# Update the range combobox values
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steps = [10, 20, 40, 80, 100, 160]
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valid_steps = sorted([s for s in steps if s <= self.max_range])
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if not valid_steps: valid_steps = [self.max_range]
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if self.max_range not in valid_steps:
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valid_steps.append(self.max_range)
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valid_steps.sort()
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self.range_selector['values'] = valid_steps
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self.range_var.set(self.max_range) # Set to the new max range
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# Update the scan limit lines
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limit_rad = np.deg2rad(self.scan_limit_deg)
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self._scan_line_1.set_xdata([limit_rad, limit_rad])
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self._scan_line_2.set_xdata([-limit_rad, -limit_rad])
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# Apply the new range and redraw everything
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self._on_range_selected() |