y2014/control_loops/drivetrain/polydrivetrain.cc - RealtimeRoboticsGroup/test - Gitiles

 #include "y2014/control_loops/drivetrain/polydrivetrain.h"

 #include "aos/common/logging/logging.h"
 #include "aos/common/controls/polytope.h"
 #include "aos/common/commonmath.h"
 #include "aos/common/logging/queue_logging.h"
 #include "aos/common/logging/matrix_logging.h"

 #include "aos/common/messages/robot_state.q.h"
 #include "frc971/control_loops/state_feedback_loop.h"
 #include "frc971/control_loops/coerce_goal.h"
 #include "y2014/constants.h"
 #include "y2014/control_loops/drivetrain/drivetrain.q.h"
 #include "y2014/control_loops/drivetrain/drivetrain_dog_motor_plant.h"

 #define HAVE_SHIFTERS 1

 namespace y2014 {
 namespace control_loops {
 namespace drivetrain {

 using ::y2014::control_loops::GearLogging;
 using ::y2014::control_loops::CIMLogging;
 using ::frc971::control_loops::CoerceGoal;

 PolyDrivetrain::PolyDrivetrain(StateFeedbackLoop<7, 2, 3> *kf)
     : kf_(kf),
       U_Poly_((Eigen::Matrix<double, 4, 2>() << /*[[*/ 1, 0 /*]*/,
                /*[*/ -1, 0 /*]*/,
                /*[*/ 0, 1 /*]*/,
                /*[*/ 0, -1 /*]]*/).finished(),
               (Eigen::Matrix<double, 4, 1>() << /*[[*/ 12 /*]*/,
                /*[*/ 12 /*]*/,
                /*[*/ 12 /*]*/,
                /*[*/ 12 /*]]*/).finished()),
       loop_(new StateFeedbackLoop<2, 2, 2>(
           constants::GetValues().make_v_drivetrain_loop())),
       ttrust_(1.1),
       wheel_(0.0),
       throttle_(0.0),
       quickturn_(false),
       stale_count_(0),
       position_time_delta_(kDt),
       left_gear_(LOW),
       right_gear_(LOW),
       counter_(0) {
   last_position_.Zero();
   position_.Zero();
 }

 double PolyDrivetrain::MotorSpeed(
     const constants::ShifterHallEffect &hall_effect, double shifter_position,
     double velocity) {
   const double avg_hall_effect =
       (hall_effect.clear_high + hall_effect.clear_low) / 2.0;

   if (shifter_position > avg_hall_effect) {
     return velocity / constants::GetValues().high_gear_ratio / kWheelRadius;
   } else {
     return velocity / constants::GetValues().low_gear_ratio / kWheelRadius;
   }
 }

 PolyDrivetrain::Gear PolyDrivetrain::UpdateSingleGear(
     Gear requested_gear, Gear current_gear) {
   const Gear shift_up =
       constants::GetValues().clutch_transmission ? HIGH : SHIFTING_UP;
   const Gear shift_down =
       constants::GetValues().clutch_transmission ? LOW : SHIFTING_DOWN;

   if (current_gear != requested_gear) {
     if (IsInGear(current_gear)) {
       if (requested_gear == HIGH) {
         if (current_gear != HIGH) {
           current_gear = shift_up;
         }
       } else {
         if (current_gear != LOW) {
           current_gear = shift_down;
         }
       }
     } else {
       if (requested_gear == HIGH && current_gear == SHIFTING_DOWN) {
         current_gear = SHIFTING_UP;
       } else if (requested_gear == LOW && current_gear == SHIFTING_UP) {
         current_gear = SHIFTING_DOWN;
       }
     }
   }
   return current_gear;
 }

 void PolyDrivetrain::UpdateGears(Gear requested_gear) {
   left_gear_ = UpdateSingleGear(requested_gear, left_gear_);
   right_gear_ = UpdateSingleGear(requested_gear, right_gear_);
 }

 void PolyDrivetrain::SetGoal(double wheel, double throttle, bool quickturn,
                              bool highgear) {
   const double kWheelNonLinearity = 0.3;
   // Apply a sin function that's scaled to make it feel better.
   const double angular_range = M_PI_2 * kWheelNonLinearity;

   wheel_ = sin(angular_range * wheel) / sin(angular_range);
   wheel_ = sin(angular_range * wheel_) / sin(angular_range);
   quickturn_ = quickturn;

   static const double kThrottleDeadband = 0.05;
   if (::std::abs(throttle) < kThrottleDeadband) {
     throttle_ = 0;
   } else {
     throttle_ = copysign(
         (::std::abs(throttle) - kThrottleDeadband) / (1.0 - kThrottleDeadband),
         throttle);
   }

   UpdateGears(highgear ? HIGH : LOW);
 }

 void PolyDrivetrain::SetPosition(
     const ::y2014::control_loops::DrivetrainQueue::Position *position) {
   if (position == NULL) {
     ++stale_count_;
   } else {
     last_position_ = position_;
     position_ = *position;
     position_time_delta_ = (stale_count_ + 1) * kDt;
     stale_count_ = 0;
   }

   if (position) {
     const auto &values = constants::GetValues();
     GearLogging gear_logging;
     // Switch to the correct controller.
     const double left_middle_shifter_position =
         (values.left_drive.clear_high + values.left_drive.clear_low) / 2.0;
     const double right_middle_shifter_position =
         (values.right_drive.clear_high + values.right_drive.clear_low) / 2.0;

     if (position->left_shifter_position < left_middle_shifter_position ||
         left_gear_ == LOW) {
       if (position->right_shifter_position < right_middle_shifter_position ||
           right_gear_ == LOW) {
         gear_logging.left_loop_high = false;
         gear_logging.right_loop_high = false;
         loop_->set_controller_index(gear_logging.controller_index = 0);
       } else {
         gear_logging.left_loop_high = false;
         gear_logging.right_loop_high = true;
         loop_->set_controller_index(gear_logging.controller_index = 1);
       }
     } else {
       if (position->right_shifter_position < right_middle_shifter_position ||
           right_gear_ == LOW) {
         gear_logging.left_loop_high = true;
         gear_logging.right_loop_high = false;
         loop_->set_controller_index(gear_logging.controller_index = 2);
       } else {
         gear_logging.left_loop_high = true;
         gear_logging.right_loop_high = true;
         loop_->set_controller_index(gear_logging.controller_index = 3);
       }
     }

     if (position->left_shifter_position > values.left_drive.clear_high &&
         left_gear_ == SHIFTING_UP) {
       left_gear_ = HIGH;
     }
     if (position->left_shifter_position < values.left_drive.clear_low &&
         left_gear_ == SHIFTING_DOWN) {
       left_gear_ = LOW;
     }
     if (position->right_shifter_position > values.right_drive.clear_high &&
         right_gear_ == SHIFTING_UP) {
       right_gear_ = HIGH;
     }
     if (position->right_shifter_position < values.right_drive.clear_low &&
         right_gear_ == SHIFTING_DOWN) {
       right_gear_ = LOW;
     }

     gear_logging.left_state = left_gear_;
     gear_logging.right_state = right_gear_;
     LOG_STRUCT(DEBUG, "state", gear_logging);
   }
 }

 double PolyDrivetrain::FilterVelocity(double throttle) {
   const Eigen::Matrix<double, 2, 2> FF =
       loop_->B().inverse() *
       (Eigen::Matrix<double, 2, 2>::Identity() - loop_->A());

   constexpr int kHighGearController = 3;
   const Eigen::Matrix<double, 2, 2> FF_high =
       loop_->controller(kHighGearController).plant.B().inverse() *
       (Eigen::Matrix<double, 2, 2>::Identity() -
        loop_->controller(kHighGearController).plant.A());

   ::Eigen::Matrix<double, 1, 2> FF_sum = FF.colwise().sum();
   int min_FF_sum_index;
   const double min_FF_sum = FF_sum.minCoeff(&min_FF_sum_index);
   const double min_K_sum = loop_->K().col(min_FF_sum_index).sum();
   const double high_min_FF_sum = FF_high.col(0).sum();

   const double adjusted_ff_voltage =
       ::aos::Clip(throttle * 12.0 * min_FF_sum / high_min_FF_sum, -12.0, 12.0);
   return (adjusted_ff_voltage +
           ttrust_ * min_K_sum * (loop_->X_hat(0, 0) + loop_->X_hat(1, 0)) /
               2.0) /
          (ttrust_ * min_K_sum + min_FF_sum);
 }

 double PolyDrivetrain::MaxVelocity() {
   const Eigen::Matrix<double, 2, 2> FF =
       loop_->B().inverse() *
       (Eigen::Matrix<double, 2, 2>::Identity() - loop_->A());

   constexpr int kHighGearController = 3;
   const Eigen::Matrix<double, 2, 2> FF_high =
       loop_->controller(kHighGearController).plant.B().inverse() *
       (Eigen::Matrix<double, 2, 2>::Identity() -
        loop_->controller(kHighGearController).plant.A());

   ::Eigen::Matrix<double, 1, 2> FF_sum = FF.colwise().sum();
   int min_FF_sum_index;
   const double min_FF_sum = FF_sum.minCoeff(&min_FF_sum_index);
   // const double min_K_sum = loop_->K().col(min_FF_sum_index).sum();
   const double high_min_FF_sum = FF_high.col(0).sum();

   const double adjusted_ff_voltage =
       ::aos::Clip(12.0 * min_FF_sum / high_min_FF_sum, -12.0, 12.0);
   return adjusted_ff_voltage / min_FF_sum;
 }

 void PolyDrivetrain::Update() {
   loop_->mutable_X_hat()(0, 0) = kf_->X_hat()(1, 0);
   loop_->mutable_X_hat()(1, 0) = kf_->X_hat()(3, 0);

   const auto &values = constants::GetValues();
   // TODO(austin): Observer for the current velocity instead of difference
   // calculations.
   ++counter_;
   const double current_left_velocity =
       (position_.left_encoder - last_position_.left_encoder) /
       position_time_delta_;
   const double current_right_velocity =
       (position_.right_encoder - last_position_.right_encoder) /
       position_time_delta_;
   const double left_motor_speed =
       MotorSpeed(values.left_drive, position_.left_shifter_position,
                  current_left_velocity);
   const double right_motor_speed =
       MotorSpeed(values.right_drive, position_.right_shifter_position,
                  current_right_velocity);

   {
     CIMLogging logging;

     // Reset the CIM model to the current conditions to be ready for when we
     // shift.
     if (IsInGear(left_gear_)) {
       logging.left_in_gear = true;
     } else {
       logging.left_in_gear = false;
     }
     logging.left_motor_speed = left_motor_speed;
     logging.left_velocity = current_left_velocity;
     if (IsInGear(right_gear_)) {
       logging.right_in_gear = true;
     } else {
       logging.right_in_gear = false;
     }
     logging.right_motor_speed = right_motor_speed;
     logging.right_velocity = current_right_velocity;

     LOG_STRUCT(DEBUG, "currently", logging);
   }

   if (IsInGear(left_gear_) && IsInGear(right_gear_)) {
     // FF * X = U (steady state)
     const Eigen::Matrix<double, 2, 2> FF =
         loop_->B().inverse() *
         (Eigen::Matrix<double, 2, 2>::Identity() - loop_->A());

     // Invert the plant to figure out how the velocity filter would have to
     // work
     // out in order to filter out the forwards negative inertia.
     // This math assumes that the left and right power and velocity are
     // equals,
     // and that the plant is the same on the left and right.
     const double fvel = FilterVelocity(throttle_);

     const double sign_svel = wheel_ * ((fvel > 0.0) ? 1.0 : -1.0);
     double steering_velocity;
     if (quickturn_) {
       steering_velocity = wheel_ * MaxVelocity();
     } else {
       steering_velocity = ::std::abs(fvel) * wheel_;
     }
     const double left_velocity = fvel - steering_velocity;
     const double right_velocity = fvel + steering_velocity;

     // Integrate velocity to get the position.
     // This position is used to get integral control.
     loop_->mutable_R() << left_velocity, right_velocity;

     if (!quickturn_) {
       // K * R = w
       Eigen::Matrix<double, 1, 2> equality_k;
       equality_k << 1 + sign_svel, -(1 - sign_svel);
       const double equality_w = 0.0;

       // Construct a constraint on R by manipulating the constraint on U
       ::aos::controls::HPolytope<2> R_poly = ::aos::controls::HPolytope<2>(
           U_Poly_.H() * (loop_->K() + FF),
           U_Poly_.k() + U_Poly_.H() * loop_->K() * loop_->X_hat());

       // Limit R back inside the box.
       loop_->mutable_R() =
           CoerceGoal(R_poly, equality_k, equality_w, loop_->R());
     }

     const Eigen::Matrix<double, 2, 1> FF_volts = FF * loop_->R();
     const Eigen::Matrix<double, 2, 1> U_ideal =
         loop_->K() * (loop_->R() - loop_->X_hat()) + FF_volts;

     for (int i = 0; i < 2; i++) {
       loop_->mutable_U()[i] = ::aos::Clip(U_ideal[i], -12, 12);
     }
   } else {
     // Any motor is not in gear.  Speed match.
     ::Eigen::Matrix<double, 1, 1> R_left;
     ::Eigen::Matrix<double, 1, 1> R_right;
     R_left(0, 0) = left_motor_speed;
     R_right(0, 0) = right_motor_speed;

     const double wiggle =
         (static_cast<double>((counter_ % 20) / 10) - 0.5) * 5.0;

     loop_->mutable_U(0, 0) = ::aos::Clip(
         (R_left / Kv)(0, 0) + (IsInGear(left_gear_) ? 0 : wiggle), -12.0, 12.0);
     loop_->mutable_U(1, 0) =
         ::aos::Clip((R_right / Kv)(0, 0) + (IsInGear(right_gear_) ? 0 : wiggle),
                     -12.0, 12.0);
     loop_->mutable_U() *= 12.0 / ::aos::robot_state->voltage_battery;
   }
 }

 void PolyDrivetrain::SendMotors(
     ::y2014::control_loops::DrivetrainQueue::Output *output) {
   if (output != NULL) {
     output->left_voltage = loop_->U(0, 0);
     output->right_voltage = loop_->U(1, 0);
     output->left_high = left_gear_ == HIGH || left_gear_ == SHIFTING_UP;
     output->right_high = right_gear_ == HIGH || right_gear_ == SHIFTING_UP;
   }
 }

 constexpr double PolyDrivetrain::kStallTorque;
 constexpr double PolyDrivetrain::kStallCurrent;
 constexpr double PolyDrivetrain::kFreeSpeed;
 constexpr double PolyDrivetrain::kFreeCurrent;
 constexpr double PolyDrivetrain::kWheelRadius;
 constexpr double PolyDrivetrain::kR;
 constexpr double PolyDrivetrain::Kv;
 constexpr double PolyDrivetrain::Kt;

 }  // namespace drivetrain
 }  // namespace control_loops
 }  // namespace y2014
	#include "y2014/control_loops/drivetrain/polydrivetrain.h"

	#include "aos/common/logging/logging.h"
	#include "aos/common/controls/polytope.h"
	#include "aos/common/commonmath.h"
	#include "aos/common/logging/queue_logging.h"
	#include "aos/common/logging/matrix_logging.h"

	#include "aos/common/messages/robot_state.q.h"
	#include "frc971/control_loops/state_feedback_loop.h"
	#include "frc971/control_loops/coerce_goal.h"
	#include "y2014/constants.h"
	#include "y2014/control_loops/drivetrain/drivetrain.q.h"
	#include "y2014/control_loops/drivetrain/drivetrain_dog_motor_plant.h"

	#define HAVE_SHIFTERS 1

	namespace y2014 {
	namespace control_loops {
	namespace drivetrain {

	using ::y2014::control_loops::GearLogging;
	using ::y2014::control_loops::CIMLogging;
	using ::frc971::control_loops::CoerceGoal;

	PolyDrivetrain::PolyDrivetrain(StateFeedbackLoop<7, 2, 3> *kf)
	: kf_(kf),
	U_Poly_((Eigen::Matrix<double, 4, 2>() << /[[/ 1, 0 /]/,
	/[/ -1, 0 /]/,
	/[/ 0, 1 /]/,
	/[/ 0, -1 /]]/).finished(),
	(Eigen::Matrix<double, 4, 1>() << /[[/ 12 /]/,
	/[/ 12 /]/,
	/[/ 12 /]/,
	/[/ 12 /]]/).finished()),
	loop_(new StateFeedbackLoop<2, 2, 2>(
	constants::GetValues().make_v_drivetrain_loop())),
	ttrust_(1.1),
	wheel_(0.0),
	throttle_(0.0),
	quickturn_(false),
	stale_count_(0),
	position_time_delta_(kDt),
	left_gear_(LOW),
	right_gear_(LOW),
	counter_(0) {
	last_position_.Zero();
	position_.Zero();
	}

	double PolyDrivetrain::MotorSpeed(
	const constants::ShifterHallEffect &hall_effect, double shifter_position,
	double velocity) {
	const double avg_hall_effect =
	(hall_effect.clear_high + hall_effect.clear_low) / 2.0;

	if (shifter_position > avg_hall_effect) {
	return velocity / constants::GetValues().high_gear_ratio / kWheelRadius;
	} else {
	return velocity / constants::GetValues().low_gear_ratio / kWheelRadius;
	}
	}

	PolyDrivetrain::Gear PolyDrivetrain::UpdateSingleGear(
	Gear requested_gear, Gear current_gear) {
	const Gear shift_up =
	constants::GetValues().clutch_transmission ? HIGH : SHIFTING_UP;
	const Gear shift_down =
	constants::GetValues().clutch_transmission ? LOW : SHIFTING_DOWN;

	if (current_gear != requested_gear) {
	if (IsInGear(current_gear)) {
	if (requested_gear == HIGH) {
	if (current_gear != HIGH) {
	current_gear = shift_up;
	}
	} else {
	if (current_gear != LOW) {
	current_gear = shift_down;
	}
	}
	} else {
	if (requested_gear == HIGH && current_gear == SHIFTING_DOWN) {
	current_gear = SHIFTING_UP;
	} else if (requested_gear == LOW && current_gear == SHIFTING_UP) {
	current_gear = SHIFTING_DOWN;
	}
	}
	}
	return current_gear;
	}

	void PolyDrivetrain::UpdateGears(Gear requested_gear) {
	left_gear_ = UpdateSingleGear(requested_gear, left_gear_);
	right_gear_ = UpdateSingleGear(requested_gear, right_gear_);
	}

	void PolyDrivetrain::SetGoal(double wheel, double throttle, bool quickturn,
	bool highgear) {
	const double kWheelNonLinearity = 0.3;
	// Apply a sin function that's scaled to make it feel better.
	const double angular_range = M_PI_2 * kWheelNonLinearity;

	wheel_ = sin(angular_range * wheel) / sin(angular_range);
	wheel_ = sin(angular_range * wheel_) / sin(angular_range);
	quickturn_ = quickturn;

	static const double kThrottleDeadband = 0.05;
	if (::std::abs(throttle) < kThrottleDeadband) {
	throttle_ = 0;
	} else {
	throttle_ = copysign(
	(::std::abs(throttle) - kThrottleDeadband) / (1.0 - kThrottleDeadband),
	throttle);
	}

	UpdateGears(highgear ? HIGH : LOW);
	}

	void PolyDrivetrain::SetPosition(
	const ::y2014::control_loops::DrivetrainQueue::Position *position) {
	if (position == NULL) {
	++stale_count_;
	} else {
	last_position_ = position_;
	position_ = *position;
	position_time_delta_ = (stale_count_ + 1) * kDt;
	stale_count_ = 0;
	}

	if (position) {
	const auto &values = constants::GetValues();
	GearLogging gear_logging;
	// Switch to the correct controller.
	const double left_middle_shifter_position =
	(values.left_drive.clear_high + values.left_drive.clear_low) / 2.0;
	const double right_middle_shifter_position =
	(values.right_drive.clear_high + values.right_drive.clear_low) / 2.0;

	if (position->left_shifter_position < left_middle_shifter_position \|\|
	left_gear_ == LOW) {
	if (position->right_shifter_position < right_middle_shifter_position \|\|
	right_gear_ == LOW) {
	gear_logging.left_loop_high = false;
	gear_logging.right_loop_high = false;
	loop_->set_controller_index(gear_logging.controller_index = 0);
	} else {
	gear_logging.left_loop_high = false;
	gear_logging.right_loop_high = true;
	loop_->set_controller_index(gear_logging.controller_index = 1);
	}
	} else {
	if (position->right_shifter_position < right_middle_shifter_position \|\|
	right_gear_ == LOW) {
	gear_logging.left_loop_high = true;
	gear_logging.right_loop_high = false;
	loop_->set_controller_index(gear_logging.controller_index = 2);
	} else {
	gear_logging.left_loop_high = true;
	gear_logging.right_loop_high = true;
	loop_->set_controller_index(gear_logging.controller_index = 3);
	}
	}

	if (position->left_shifter_position > values.left_drive.clear_high &&
	left_gear_ == SHIFTING_UP) {
	left_gear_ = HIGH;
	}
	if (position->left_shifter_position < values.left_drive.clear_low &&
	left_gear_ == SHIFTING_DOWN) {
	left_gear_ = LOW;
	}
	if (position->right_shifter_position > values.right_drive.clear_high &&
	right_gear_ == SHIFTING_UP) {
	right_gear_ = HIGH;
	}
	if (position->right_shifter_position < values.right_drive.clear_low &&
	right_gear_ == SHIFTING_DOWN) {
	right_gear_ = LOW;
	}

	gear_logging.left_state = left_gear_;
	gear_logging.right_state = right_gear_;
	LOG_STRUCT(DEBUG, "state", gear_logging);
	}
	}

	double PolyDrivetrain::FilterVelocity(double throttle) {
	const Eigen::Matrix<double, 2, 2> FF =
	loop_->B().inverse() *
	(Eigen::Matrix<double, 2, 2>::Identity() - loop_->A());

	constexpr int kHighGearController = 3;
	const Eigen::Matrix<double, 2, 2> FF_high =
	loop_->controller(kHighGearController).plant.B().inverse() *
	(Eigen::Matrix<double, 2, 2>::Identity() -
	loop_->controller(kHighGearController).plant.A());

	::Eigen::Matrix<double, 1, 2> FF_sum = FF.colwise().sum();
	int min_FF_sum_index;
	const double min_FF_sum = FF_sum.minCoeff(&min_FF_sum_index);
	const double min_K_sum = loop_->K().col(min_FF_sum_index).sum();
	const double high_min_FF_sum = FF_high.col(0).sum();

	const double adjusted_ff_voltage =
	::aos::Clip(throttle * 12.0 * min_FF_sum / high_min_FF_sum, -12.0, 12.0);
	return (adjusted_ff_voltage +
	ttrust_ * min_K_sum * (loop_->X_hat(0, 0) + loop_->X_hat(1, 0)) /
	2.0) /
	(ttrust_ * min_K_sum + min_FF_sum);
	}

	double PolyDrivetrain::MaxVelocity() {
	const Eigen::Matrix<double, 2, 2> FF =
	loop_->B().inverse() *
	(Eigen::Matrix<double, 2, 2>::Identity() - loop_->A());

	constexpr int kHighGearController = 3;
	const Eigen::Matrix<double, 2, 2> FF_high =
	loop_->controller(kHighGearController).plant.B().inverse() *
	(Eigen::Matrix<double, 2, 2>::Identity() -
	loop_->controller(kHighGearController).plant.A());

	::Eigen::Matrix<double, 1, 2> FF_sum = FF.colwise().sum();
	int min_FF_sum_index;
	const double min_FF_sum = FF_sum.minCoeff(&min_FF_sum_index);
	// const double min_K_sum = loop_->K().col(min_FF_sum_index).sum();
	const double high_min_FF_sum = FF_high.col(0).sum();

	const double adjusted_ff_voltage =
	::aos::Clip(12.0 * min_FF_sum / high_min_FF_sum, -12.0, 12.0);
	return adjusted_ff_voltage / min_FF_sum;
	}

	void PolyDrivetrain::Update() {
	loop_->mutable_X_hat()(0, 0) = kf_->X_hat()(1, 0);
	loop_->mutable_X_hat()(1, 0) = kf_->X_hat()(3, 0);

	const auto &values = constants::GetValues();
	// TODO(austin): Observer for the current velocity instead of difference
	// calculations.
	++counter_;
	const double current_left_velocity =
	(position_.left_encoder - last_position_.left_encoder) /
	position_time_delta_;
	const double current_right_velocity =
	(position_.right_encoder - last_position_.right_encoder) /
	position_time_delta_;
	const double left_motor_speed =
	MotorSpeed(values.left_drive, position_.left_shifter_position,
	current_left_velocity);
	const double right_motor_speed =
	MotorSpeed(values.right_drive, position_.right_shifter_position,
	current_right_velocity);

	{
	CIMLogging logging;

	// Reset the CIM model to the current conditions to be ready for when we
	// shift.
	if (IsInGear(left_gear_)) {
	logging.left_in_gear = true;
	} else {
	logging.left_in_gear = false;
	}
	logging.left_motor_speed = left_motor_speed;
	logging.left_velocity = current_left_velocity;
	if (IsInGear(right_gear_)) {
	logging.right_in_gear = true;
	} else {
	logging.right_in_gear = false;
	}
	logging.right_motor_speed = right_motor_speed;
	logging.right_velocity = current_right_velocity;

	LOG_STRUCT(DEBUG, "currently", logging);
	}

	if (IsInGear(left_gear_) && IsInGear(right_gear_)) {
	// FF * X = U (steady state)
	const Eigen::Matrix<double, 2, 2> FF =
	loop_->B().inverse() *
	(Eigen::Matrix<double, 2, 2>::Identity() - loop_->A());

	// Invert the plant to figure out how the velocity filter would have to
	// work
	// out in order to filter out the forwards negative inertia.
	// This math assumes that the left and right power and velocity are
	// equals,
	// and that the plant is the same on the left and right.
	const double fvel = FilterVelocity(throttle_);

	const double sign_svel = wheel_ * ((fvel > 0.0) ? 1.0 : -1.0);
	double steering_velocity;
	if (quickturn_) {
	steering_velocity = wheel_ * MaxVelocity();
	} else {
	steering_velocity = ::std::abs(fvel) * wheel_;
	}
	const double left_velocity = fvel - steering_velocity;
	const double right_velocity = fvel + steering_velocity;

	// Integrate velocity to get the position.
	// This position is used to get integral control.
	loop_->mutable_R() << left_velocity, right_velocity;

	if (!quickturn_) {
	// K * R = w
	Eigen::Matrix<double, 1, 2> equality_k;
	equality_k << 1 + sign_svel, -(1 - sign_svel);
	const double equality_w = 0.0;

	// Construct a constraint on R by manipulating the constraint on U
	::aos::controls::HPolytope<2> R_poly = ::aos::controls::HPolytope<2>(
	U_Poly_.H() * (loop_->K() + FF),
	U_Poly_.k() + U_Poly_.H() * loop_->K() * loop_->X_hat());

	// Limit R back inside the box.
	loop_->mutable_R() =
	CoerceGoal(R_poly, equality_k, equality_w, loop_->R());
	}

	const Eigen::Matrix<double, 2, 1> FF_volts = FF * loop_->R();
	const Eigen::Matrix<double, 2, 1> U_ideal =
	loop_->K() * (loop_->R() - loop_->X_hat()) + FF_volts;

	for (int i = 0; i < 2; i++) {
	loop_->mutable_U()[i] = ::aos::Clip(U_ideal[i], -12, 12);
	}
	} else {
	// Any motor is not in gear. Speed match.
	::Eigen::Matrix<double, 1, 1> R_left;
	::Eigen::Matrix<double, 1, 1> R_right;
	R_left(0, 0) = left_motor_speed;
	R_right(0, 0) = right_motor_speed;

	const double wiggle =
	(static_cast<double>((counter_ % 20) / 10) - 0.5) * 5.0;

	loop_->mutable_U(0, 0) = ::aos::Clip(
	(R_left / Kv)(0, 0) + (IsInGear(left_gear_) ? 0 : wiggle), -12.0, 12.0);
	loop_->mutable_U(1, 0) =
	::aos::Clip((R_right / Kv)(0, 0) + (IsInGear(right_gear_) ? 0 : wiggle),
	-12.0, 12.0);
	loop_->mutable_U() *= 12.0 / ::aos::robot_state->voltage_battery;
	}
	}

	void PolyDrivetrain::SendMotors(
	::y2014::control_loops::DrivetrainQueue::Output *output) {
	if (output != NULL) {
	output->left_voltage = loop_->U(0, 0);
	output->right_voltage = loop_->U(1, 0);
	output->left_high = left_gear_ == HIGH \|\| left_gear_ == SHIFTING_UP;
	output->right_high = right_gear_ == HIGH \|\| right_gear_ == SHIFTING_UP;
	}
	}

	constexpr double PolyDrivetrain::kStallTorque;
	constexpr double PolyDrivetrain::kStallCurrent;
	constexpr double PolyDrivetrain::kFreeSpeed;
	constexpr double PolyDrivetrain::kFreeCurrent;
	constexpr double PolyDrivetrain::kWheelRadius;
	constexpr double PolyDrivetrain::kR;
	constexpr double PolyDrivetrain::Kv;
	constexpr double PolyDrivetrain::Kt;

	} // namespace drivetrain
	} // namespace control_loops
	} // namespace y2014