Fix goToAngle with new odom

server_v2/CMakeLists.txt

@@ -22,10 +22,11 @@ if (UNIX AND ${CMAKE_SYSTEM_PROCESSOR} STREQUAL armv7l)
     set(LIBRARIES "pigpio" "spdlog::spdlog")
     set(CMAKE_CXX_FLAGS "-Wall -Wextra -Wno-psabi")
 
-    set(IS_RASPI)
+    set(IS_RASPI true)
 endif ()
 
 if (NOT IS_RASPI)
+    message("NOT Running on RaspberryPi")
     set(CMAKE_CXX_FLAGS_DEBUG "-g -O0")
     set(CMAKE_CXX_FLAGS_DEBUG "${CMAKE_CXX_FLAGS_DEBUG} -gdwarf-3")
     set(CMAKE_C_FLAGS_DEBUG "${CMAKE_C_FLAGS_DEBUG} -Wall -Wextra -gdwarf-3")

server_v2/include/Robot.hpp

@@ -34,9 +34,9 @@
 
 #define ROBOT_GO_TO_DISTANCE_RATE_HZ 200
 #define ROBOT_GO_TO_DISTANCE_ALPHA_P 2.0
-#define ROBOT_GO_TO_DISTANCE_VELOCITY_P 4.0
+#define ROBOT_GO_TO_DISTANCE_VELOCITY_P 10.0
 #define ROBOT_GO_TO_DISTANCE_END_M 0.01 // stop approx 1 cm before target
-#define ROBOT_GO_TO_DISTANCE_MIN_VEL 0.025
+#define ROBOT_GO_TO_DISTANCE_MIN_VEL 0.075
 
 #define ROBOT_GO_TO_ANGLE_RATE_HZ 200
 #define ROBOT_GO_TO_ANGLE_END_RAD (0.5 * (M_PI / 180.0)) // stop 0.5 deg before target

server_v2/src/GoToController.cpp

@@ -12,8 +12,8 @@
 // Source: http://faculty.salina.k-state.edu/tim/robot_prog/MobileBot/Steering/unicycle.html#calculating-wheel-velocities
 // Source: https://www.roboticsbook.org/S52_diffdrive_actions.html#kinematics-in-code
 void GoToController::diff_drive_inverse_kinematics(double v_m_s, double w_rad_s) {
-  auto vr_rad_s = (2 * v_m_s - w_rad_s * ROBOT_ARBOR_LENGTH_M) / (2.0 * ROBOT_WHEEL_RADIUS_M) * ROBOT_ODOMETRY_CONTROLLER_RIGHT_MULT;
+  auto vr_rad_s = (2 * v_m_s + w_rad_s * ROBOT_ARBOR_LENGTH_M) / (2.0 * ROBOT_WHEEL_RADIUS_M) * ROBOT_ODOMETRY_CONTROLLER_RIGHT_MULT;
-  auto vl_rad_s = (2 * v_m_s + w_rad_s * ROBOT_ARBOR_LENGTH_M) / (2.0 * ROBOT_WHEEL_RADIUS_M) * ROBOT_ODOMETRY_CONTROLLER_LEFT_MULT;
+  auto vl_rad_s = (2 * v_m_s - w_rad_s * ROBOT_ARBOR_LENGTH_M) / (2.0 * ROBOT_WHEEL_RADIUS_M) * ROBOT_ODOMETRY_CONTROLLER_LEFT_MULT;
 
   ClosedLoopMotorController::getInstance().set_speed(ROBOT_ODOMETRY_CONTROLLER_RIGHT_PORT, vr_rad_s);
   ClosedLoopMotorController::getInstance().set_speed(ROBOT_ODOMETRY_CONTROLLER_LEFT_PORT, vl_rad_s);
@@ -100,6 +100,11 @@ void GoToController::turn_degrees(double angle_deg, double v_rad_s) {
     }
   }
 
+  ClosedLoopMotorController::getInstance().set_speed(ROBOT_ODOMETRY_CONTROLLER_RIGHT_PORT, 0);
+  ClosedLoopMotorController::getInstance().set_speed(ROBOT_ODOMETRY_CONTROLLER_LEFT_PORT, 0);
+
+  std::this_thread::sleep_for(std::chrono::milliseconds(50));
+
   ClosedLoopMotorController::getInstance().set_power(ROBOT_ODOMETRY_CONTROLLER_RIGHT_PORT, 0);
   ClosedLoopMotorController::getInstance().set_power(ROBOT_ODOMETRY_CONTROLLER_LEFT_PORT, 0);
 

server_v2/src/OdometryController.cpp

@@ -10,80 +10,80 @@
 #define US_IN_S (1000 * MS_IN_S)
 
 bool OdometryController::is_enabled() const {
-    return enabled;
+  return enabled;
 }
 
 void OdometryController::enable() {
-    last_run = clock::now();
+  last_run = clock::now();
-    enabled = true;
+  enabled = true;
 }
 
 void OdometryController::disable() {
-    spdlog::debug("OdometryController::disable()");
+  spdlog::debug("OdometryController::disable()");
-    enabled = false;
+  enabled = false;
-    OdometryController::reset();
+  OdometryController::reset();
 }
 
 void OdometryController::reset() {
-    std::lock_guard<std::recursive_mutex> lock(odometry_mutex);
+  std::lock_guard<std::recursive_mutex> lock(odometry_mutex);
-    current_odometry = Odometry();
+  current_odometry = Odometry();
-    last_run = clock::now();
+  last_run = clock::now();
 }
 
 Odometry OdometryController::get() {
-    return current_odometry;
+  return current_odometry;
 }
 
 
 OdometryController::OdometryController() {
-    odometry_thread = std::thread(&OdometryController::odometry_loop, this);
+  odometry_thread = std::thread(&OdometryController::odometry_loop, this);
-    odometry_thread.detach();
+  odometry_thread.detach();
 }
 
 [[noreturn]] void OdometryController::odometry_loop() {
-    auto sleep_duration = std::chrono::microseconds(US_IN_S / ROBOT_ODOMETRY_CONTROLLER_RATE_HZ);
+  auto sleep_duration = std::chrono::microseconds(US_IN_S / ROBOT_ODOMETRY_CONTROLLER_RATE_HZ);
-    while (true) {
+  while (true) {
-        std::this_thread::sleep_for(sleep_duration);
+    std::this_thread::sleep_for(sleep_duration);
-        std::lock_guard<std::recursive_mutex> lock(odometry_mutex);
+    std::lock_guard<std::recursive_mutex> lock(odometry_mutex);
-        if (enabled) {
+    if (enabled) {
-            last_run = clock::now();
+      last_run = clock::now();
-            auto encoder_positions = Encoders::getInstance().get_positions();
+      auto encoder_positions = Encoders::getInstance().get_positions();
 
-            auto current_position_left =
+      auto current_position_left =
-                    encoder_positions.at(ROBOT_ODOMETRY_CONTROLLER_LEFT_PORT) * ROBOT_ODOMETRY_CONTROLLER_LEFT_MULT;
+          encoder_positions.at(ROBOT_ODOMETRY_CONTROLLER_LEFT_PORT) * ROBOT_ODOMETRY_CONTROLLER_LEFT_MULT;
-            auto current_position_right =
+      auto current_position_right =
-                    encoder_positions.at(ROBOT_ODOMETRY_CONTROLLER_RIGHT_PORT) * ROBOT_ODOMETRY_CONTROLLER_RIGHT_MULT;
+          encoder_positions.at(ROBOT_ODOMETRY_CONTROLLER_RIGHT_PORT) * ROBOT_ODOMETRY_CONTROLLER_RIGHT_MULT;
-            auto distance_left = (current_position_left - last_position_left) / ROBOT_TICKS_PER_METER;
+      auto distance_left = (current_position_left - last_position_left) / ROBOT_TICKS_PER_METER;
-            auto distance_right = (current_position_right - last_position_right) / ROBOT_TICKS_PER_METER;
+      auto distance_right = (current_position_right - last_position_right) / ROBOT_TICKS_PER_METER;
-            last_position_left = current_position_left;
+      last_position_left = current_position_left;
-            last_position_right = current_position_right;
+      last_position_right = current_position_right;
 
-            // The section below implements differential drive kinematics.
+      // The section below implements differential drive kinematics.
-            // Refer to Computational Principles of Mobile Robotics, Dudek and Jenkin
+      // Refer to Computational Principles of Mobile Robotics, Dudek and Jenkin
-            //    or Chapter "Mobile Robot Kinematics" Introduction to Autonomous Mobile Robots, Roland Siegwart
+      //    or Chapter "Mobile Robot Kinematics" Introduction to Autonomous Mobile Robots, Roland Siegwart
-            //    and Illah R. Nourbakhsh
+      //    and Illah R. Nourbakhsh
-            auto v = (distance_right + distance_left) / 2.0;
+      auto v = (distance_right + distance_left) / 2.0;
-            auto w = (distance_right - distance_left) / ROBOT_ARBOR_LENGTH_M;
+      auto w = (distance_right - distance_left) / ROBOT_ARBOR_LENGTH_M;
 
-            auto curr_x = current_odometry.get_x_position();
+      auto curr_x = current_odometry.get_x_position();
-            auto curr_y = current_odometry.get_y_position();
+      auto curr_y = current_odometry.get_y_position();
-            auto curr_theta = current_odometry.get_angular_orientation();
+      auto curr_theta = current_odometry.get_angular_orientation();
 
-            auto x = v * cos(w);
+      auto x = v * cos(w);
-            auto y = v * sin(w);
+      auto y = v * sin(w);
 
-            auto new_x = curr_x + (cos(curr_theta) * x - sin(curr_theta) * y);
+      auto new_x = curr_x + (cos(curr_theta) * x - sin(curr_theta) * y);
-            auto new_y = curr_y + (sin(curr_theta) * x + cos(curr_theta) * y);
+      auto new_y = curr_y + (sin(curr_theta) * x + cos(curr_theta) * y);
-            auto new_theta = curr_theta + w;
+      auto new_theta = curr_theta + w;
 
-            new_theta = mathUtils::wrap_angle_to_pi(new_theta);
+      new_theta = mathUtils::wrap_angle_to_pi(new_theta);
-            current_odometry = Odometry(new_x, new_y, new_theta);
+      current_odometry = Odometry(new_x, new_y, new_theta);
 
 
-//      spdlog::info("{:03.4f} {:03.4f} {:03.4f} {:03.4f} {:03.4f} {:03.4f}",
+      spdlog::info("{:03.4f} {:03.4f} {:03.4f} {:03.4f} {:03.4f} {:03.4f}",
-//                   current_position_left, current_position_right,
+                   current_position_left, current_position_right,
-//                   distance_left, distance_right,
+                   distance_left, distance_right,
-//                   dist_forward, dist_rot);
+                   v, w);
-        }
     }
+  }
 }

server_v2/src/main.cpp

@@ -39,7 +39,7 @@ int main(int argc, char *argv[]) {
 
 //  GoToGoalController::go_to_point(2, 0, 0.2);
 //  GoToController::drive_distance(-4, 0.2);
-//  GoToController::turn_degrees(90, M_PI);
+//  GoToController::turn_degrees(180, M_PI);
 //  while (true) {
 //    this_thread::sleep_for(std::chrono::milliseconds(10));
 //    ClosedLoopMotorController::getInstance().set_power(0, 100);
@@ -50,17 +50,20 @@ int main(int argc, char *argv[]) {
 //  std::this_thread::sleep_for(std::chrono::seconds(2));
 //  GoToController::drive_distance(-2, 0.3);
 
-//  GoToController::drive_distance(2, 0.2);
+//  while (true) {
-//  GoToController::turn_degrees(-90, M_PI_2);
+//    GoToController::drive_distance(0.2, 0.4);
+//    GoToController::turn_degrees(90, M_PI_2);
 //
-//  GoToController::drive_distance(2, 0.2);
+//    GoToController::drive_distance(0.2, 0.4);
-//  GoToController::turn_degrees(-90, M_PI_2);
+//    GoToController::turn_degrees(90, M_PI_2);
 //
-//  GoToController::drive_distance(2, 0.2);
+//    GoToController::drive_distance(0.2, 0.4);
-//  GoToController::turn_degrees(-90, M_PI_2);
+//    GoToController::turn_degrees(90, M_PI_2);
 //
-//  GoToController::drive_distance(2, 0.2);
+//    GoToController::drive_distance(0.2, 0.4);
-//  GoToController::turn_degrees(-90, M_PI_2);
+//    GoToController::turn_degrees(90, M_PI_2);
+//  }
+
 
 //  ClosedLoopMotorController::getInstance().calibrate_wheel_ticks(10, stoi(argv[1]));