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realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / c44d0d7211e0912562eed939410d594b23b51a43 / . / y2015 / actors / drivetrain_actor.cc
blob: 91873eb74331f888be9424fb72ab064c96f63579 [file] [log] [blame]
#include "y2015/actors/drivetrain_actor.h"
#include <functional>
#include <numeric>
#include <Eigen/Dense>
#include "aos/common/util/phased_loop.h"
#include "aos/common/logging/logging.h"
#include "aos/common/util/trapezoid_profile.h"
#include "aos/common/commonmath.h"
#include "aos/common/time.h"
#include "frc971/control_loops/drivetrain/drivetrain.q.h"
#include "y2015/actors/drivetrain_actor.h"
#include "y2015/constants.h"
namespace y2015 {
namespace actors {
namespace chrono = ::std::chrono;
using ::frc971::control_loops::drivetrain_queue;
DrivetrainActor::DrivetrainActor(actors::DrivetrainActionQueueGroup* s)
: aos::common::actions::ActorBase<actors::DrivetrainActionQueueGroup>(s) {}
bool DrivetrainActor::RunAction(const actors::DrivetrainActionParams &params) {
static const auto K =
constants::GetValues().make_drivetrain_loop().controller().K();
const double yoffset = params.y_offset;
const double turn_offset =
params.theta_offset * constants::GetValues().turn_width / 2.0;
LOG(INFO, "Going to move %f and turn %f\n", yoffset, turn_offset);
// Measured conversion to get the distance right.
::aos::util::TrapezoidProfile profile(chrono::milliseconds(5));
::aos::util::TrapezoidProfile turn_profile(chrono::milliseconds(5));
const double goal_velocity = 0.0;
const double epsilon = 0.01;
::Eigen::Matrix<double, 2, 1> left_goal_state, right_goal_state;
profile.set_maximum_acceleration(params.maximum_acceleration);
profile.set_maximum_velocity(params.maximum_velocity);
turn_profile.set_maximum_acceleration(params.maximum_turn_acceleration *
constants::GetValues().turn_width /
2.0);
turn_profile.set_maximum_velocity(params.maximum_turn_velocity *
constants::GetValues().turn_width / 2.0);
::aos::time::PhasedLoop phased_loop(::std::chrono::milliseconds(5),
::std::chrono::milliseconds(5) / 2);
while (true) {
phased_loop.SleepUntilNext();
drivetrain_queue.status.FetchLatest();
if (drivetrain_queue.status.get()) {
const auto& status = *drivetrain_queue.status;
if (::std::abs(status.uncapped_left_voltage -
status.uncapped_right_voltage) > 24) {
LOG(DEBUG, "spinning in place\n");
// They're more than 24V apart, so stop moving forwards and let it deal
// with spinning first.
profile.SetGoal(
(status.estimated_left_position + status.estimated_right_position -
params.left_initial_position - params.right_initial_position) /
2.0);
} else {
static const double divisor = K(0, 0) + K(0, 2);
double dx_left, dx_right;
if (status.uncapped_left_voltage > 12.0) {
dx_left = (status.uncapped_left_voltage - 12.0) / divisor;
} else if (status.uncapped_left_voltage < -12.0) {
dx_left = (status.uncapped_left_voltage + 12.0) / divisor;
} else {
dx_left = 0;
}
if (status.uncapped_right_voltage > 12.0) {
dx_right = (status.uncapped_right_voltage - 12.0) / divisor;
} else if (status.uncapped_right_voltage < -12.0) {
dx_right = (status.uncapped_right_voltage + 12.0) / divisor;
} else {
dx_right = 0;
}
double dx;
if (dx_left == 0 && dx_right == 0) {
dx = 0;
} else if (dx_left != 0 && dx_right != 0 &&
::aos::sign(dx_left) != ::aos::sign(dx_right)) {
// Both saturating in opposite directions. Don't do anything.
LOG(DEBUG, "Saturating opposite ways, not adjusting\n");
dx = 0;
} else if (::std::abs(dx_left) > ::std::abs(dx_right)) {
dx = dx_left;
} else {
dx = dx_right;
}
if (dx != 0) {
LOG(DEBUG, "adjusting goal by %f\n", dx);
profile.MoveGoal(-dx);
}
}
} else {
// If we ever get here, that's bad and we should just give up
LOG(ERROR, "no drivetrain status!\n");
return false;
}
const auto drive_profile_goal_state =
profile.Update(yoffset, goal_velocity);
const auto turn_profile_goal_state = turn_profile.Update(turn_offset, 0.0);
left_goal_state = drive_profile_goal_state - turn_profile_goal_state;
right_goal_state = drive_profile_goal_state + turn_profile_goal_state;
if (::std::abs(drive_profile_goal_state(0, 0) - yoffset) < epsilon &&
::std::abs(turn_profile_goal_state(0, 0) - turn_offset) < epsilon) {
break;
}
if (ShouldCancel()) return true;
LOG(DEBUG, "Driving left to %f, right to %f\n",
left_goal_state(0, 0) + params.left_initial_position,
right_goal_state(0, 0) + params.right_initial_position);
drivetrain_queue.goal.MakeWithBuilder()
.control_loop_driving(true)
//.highgear(false)
.left_goal(left_goal_state(0, 0) + params.left_initial_position)
.right_goal(right_goal_state(0, 0) + params.right_initial_position)
.left_velocity_goal(left_goal_state(1, 0))
.right_velocity_goal(right_goal_state(1, 0))
.Send();
}
if (ShouldCancel()) return true;
drivetrain_queue.status.FetchLatest();
while (!drivetrain_queue.status.get()) {
LOG(WARNING,
"No previous drivetrain status packet, trying to fetch again\n");
drivetrain_queue.status.FetchNextBlocking();
if (ShouldCancel()) return true;
}
while (true) {
if (ShouldCancel()) return true;
const double kPositionThreshold = 0.05;
const double left_error =
::std::abs(drivetrain_queue.status->estimated_left_position -
(left_goal_state(0, 0) + params.left_initial_position));
const double right_error =
::std::abs(drivetrain_queue.status->estimated_right_position -
(right_goal_state(0, 0) + params.right_initial_position));
const double velocity_error =
::std::abs(drivetrain_queue.status->robot_speed);
if (left_error < kPositionThreshold && right_error < kPositionThreshold &&
velocity_error < 0.2) {
break;
} else {
LOG(DEBUG, "Drivetrain error is %f, %f, %f\n", left_error, right_error,
velocity_error);
}
drivetrain_queue.status.FetchNextBlocking();
}
LOG(INFO, "Done moving\n");
return true;
}
::std::unique_ptr<DrivetrainAction> MakeDrivetrainAction(
const ::y2015::actors::DrivetrainActionParams& params) {
return ::std::unique_ptr<DrivetrainAction>(
new DrivetrainAction(&::y2015::actors::drivetrain_action, params));
}
} // namespace actors
} // namespace y2015