优化项目结构

src/main.cpp

@@ -0,0 +1,237 @@
+#include <iostream>
+#include <string>
+#include <vector>
+#include <chrono>
+#include <thread>
+
+#include <opencv2/opencv.hpp>
+
+#include "config.h"
+#include "MindVisionCamera.h"  // 使用MindVision相机
+#include "ImagePreprocessor.h"
+#include "ArmorDetector.h"
+#include "KalmanFilter.h"
+#include "Visualizer.h"
+#include "BallisticPredictor.h"
+#include "TTLCommunicator.h"
+
+// Function to output control data to TTL device (with enable control)
+void output_control_data(const cv::Point2f* ballistic_point,
+                        const std::string& target_color,
+                        int frame_counter,
+                        TTLCommunicator* ttl_communicator,
+                        const cv::Point2f& img_center,
+                        bool use_ttl,
+                        bool armor_detected) {
+    // Only send data when TTL is enabled, meets frame interval, AND armor is detected
+    if (use_ttl && frame_counter % 5 == 0 && armor_detected) {
+        // Only send if we have a valid ballistic point to send
+        if (ballistic_point != nullptr) {
+            // Calculate offset (based on actual image center)
+            int ballistic_offset_x = static_cast<int>(ballistic_point->x - img_center.x);
+            int ballistic_offset_y = static_cast<int>(ballistic_point->y - img_center.y);
+
+            // Color simplification mapping
+            std::string simplified_color = target_color;
+            if (target_color == "red") simplified_color = "r";
+            else if (target_color == "blue") simplified_color = "b";
+
+            // Construct send string
+            std::string send_str = "s " + simplified_color + " " + std::to_string(ballistic_offset_x) + " " + std::to_string(ballistic_offset_y);
+
+            // Send data
+            if (ttl_communicator != nullptr) {
+                ttl_communicator->send_data(send_str);
+            }
+        }
+        // Note: When ballistic_point is nullptr, no TTL data is sent (fulfilling the requirement)
+    }
+}
+
+void set_camera_resolution(MindVisionCamera, int width, int height) {
+    // The resolution is set during camera initialization in MindVision
+    // We already set it in MindVisionCamera constructor, so this is for logging only
+    std::cout << "Camera resolution already set to: " << width << "x" << height << " during initialization" << std::endl;
+}
+
+int main(int /*argc*/, char* /*argv*/[]) {
+    std::string target_color = "red";
+    int cam_id = 0;
+    cv::Size default_resolution(640, 480); // This will be set by MindVisionCamera constructor
+    bool use_ttl = true; // Set to false to disable TTL communication
+
+    // Define optional resolution list (adjust based on camera support)
+    std::vector<cv::Size> resolutions = {
+        cv::Size(320, 240),   // Low resolution, high frame rate
+        cv::Size(640, 480),   // Standard resolution
+        cv::Size(1280, 720),  // HD resolution
+        cv::Size(1920, 1080)  // Full HD resolution
+    };
+
+    // Find the index of default resolution
+    int res_index = 1; // Default to index 1 (640x480)
+    for (size_t i = 0; i < resolutions.size(); i++) {
+        if (resolutions[i] == default_resolution) {
+            res_index = static_cast<int>(i);
+            break;
+        }
+    }
+
+    // Initialize TTL communication (only when enabled)
+    TTLCommunicator* ttl = nullptr;
+    if (use_ttl) {
+        ttl = new TTLCommunicator(TTL_BAUDRATE);
+        if (!ttl->connect()) {
+            std::cout << "Warning: Cannot establish TTL connection, will continue running but not send data" << std::endl;
+        }
+    } else {
+        std::cout << "TTL communication disabled" << std::endl;
+    }
+
+    // Initialize visual processing modules with MindVision camera
+    MindVisionCamera camera(cam_id, target_color);
+    if (!camera.is_opened) {
+        std::cerr << "Cannot open MindVision camera!" << std::endl;
+        return -1;
+    }
+
+    // Initialize ballistic predictor (adjustable bullet speed, e.g., 16m/s)
+    BallisticPredictor ballistic_predictor(16.0f);
+    // Record target speed (obtained from Kalman filter)
+    cv::Point2f target_speed(0.0f, 0.0f);
+
+    // Set initial resolution
+    set_camera_resolution(camera, resolutions[res_index].width, resolutions[res_index].height);
+    std::cout << "Initial camera resolution: " << resolutions[res_index].width << "x" << resolutions[res_index].height << std::endl;
+
+    ImagePreprocessor preprocessor;
+    ArmorDetector detector;
+    KalmanFilter kalman_tracker;
+    Visualizer visualizer;
+
+    int frame_counter = 0; // Counter to control output frequency
+    int max_consecutive_predicts = 20; // Maximum consecutive prediction times
+    int consecutive_predicts = 0; // Current consecutive prediction count
+
+    cv::Mat frame;
+    try {
+        while (true) {
+            //if (!camera.read_frame(frame)) {
+            //    std::cout << "Cannot read from MindVision camera, exiting!" << std::endl;
+            //    break;
+            //}
+
+            // Get actual image size and calculate center
+            cv::Point2f img_center(frame.cols / 2.0f, frame.rows / 2.0f);
+
+            // Preprocessing
+            cv::Mat mask, color_only_frame;
+            preprocessor.process_frame(frame, target_color, mask, color_only_frame);
+
+            // Armor plate detection
+            std::vector<LightBar> valid_light_bars;
+            std::vector<ArmorPlate> armor_plates;
+            detector.detect(mask, target_color, valid_light_bars, armor_plates);
+
+            // Kalman filter tracking (modified part: get target speed)
+            cv::Point2f* current_center = nullptr;
+            if (!armor_plates.empty()) {
+                current_center = &(armor_plates[0].center);
+            }
+
+            cv::Point2f* predicted_center = nullptr;
+
+            if (current_center != nullptr) {
+                // Has detection result: update Kalman filter, reset consecutive prediction count
+                kalman_tracker.update(*current_center);
+                predicted_center = new cv::Point2f(kalman_tracker.predict());
+
+                // Get velocity from the Kalman filter
+                target_speed = cv::Point2f(0.0f, 0.0f); // Kalman filter in OpenCV doesn't directly expose velocity
+                consecutive_predicts = 0;
+            } else {
+                // No detection result: only use Kalman prediction, limit consecutive predictions
+                consecutive_predicts++;
+                if (consecutive_predicts < max_consecutive_predicts) {
+                    cv::Point2f temp_pred = kalman_tracker.predict();
+                    if (temp_pred.x != 0 || temp_pred.y != 0) { // Check if prediction is valid
+                        predicted_center = new cv::Point2f(temp_pred);
+                    }
+                } else {
+                    predicted_center = nullptr;
+                    target_speed = cv::Point2f(0.0f, 0.0f);
+                }
+            }
+
+            // Determine display center
+            cv::Point2f* display_center = current_center;
+            if (display_center == nullptr && predicted_center != nullptr) {
+                display_center = predicted_center;
+            }
+            bool is_predicted = (display_center != nullptr) && (current_center == nullptr);
+
+            // Calculate ballistic prediction point
+            cv::Point2f* ballistic_point = ballistic_predictor.predict_ballistic_point(
+                predicted_center, img_center, target_speed
+            );
+
+            auto current_time = std::chrono::high_resolution_clock::now();
+
+            // Visualization
+            visualizer.draw_light_bars(frame, valid_light_bars, target_color);
+            if (!armor_plates.empty()) {
+                visualizer.draw_armor_plate(frame, armor_plates[0]);
+            }
+            visualizer.draw_offset_text(frame, display_center, target_color, is_predicted);
+            visualizer.draw_ballistic_point(frame, ballistic_point);
+
+            // Output control data to TTL (passing use_ttl to control whether to send)
+            // Only send TTL data if actual armor plates were detected (not just predicted)
+            bool armor_detected = !armor_plates.empty();
+            // Only send TTL data when we have an actual detection, not just prediction
+            bool should_send_ttl = armor_detected && (display_center != nullptr);
+            output_control_data(display_center, target_color, frame_counter, ttl, img_center, use_ttl, should_send_ttl);
+
+            // Display windows
+            cv::imshow("Armor Detection", frame);
+            cv::imshow(target_color + " Mask", mask);
+            cv::imshow(target_color + " Only", color_only_frame);
+
+            // Exit on 'q' key press
+            if (cv::waitKey(1) == 'q') {
+                break;
+            }
+
+            frame_counter++;
+
+            // Control max frame rate (100 FPS)
+            auto end_time = std::chrono::high_resolution_clock::now();
+            auto elapsed = std::chrono::duration_cast<std::chrono::milliseconds>(end_time - current_time).count();
+            if (elapsed < 10) { // 100 FPS = 10ms per frame
+                std::this_thread::sleep_for(std::chrono::milliseconds(30 - elapsed));
+            }
+
+            // Clean up dynamically allocated memory
+            if (predicted_center != nullptr) {
+                delete predicted_center;
+                predicted_center = nullptr;
+            }
+        }
+    }
+    catch (const std::exception& e) {
+        std::cerr << "Error: " << e.what() << std::endl;
+    }
+
+    // Cleanup
+    camera.release();
+    cv::destroyAllWindows();
+
+    // Only close TTL connection when enabled and initialized
+    if (use_ttl && ttl != nullptr) {
+        ttl->close();
+        delete ttl;
+        ttl = nullptr;
+    }
+
+    return 0;
+}