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realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / 11e61afdc9fdbea03f79e99f889fb2adb23f8b84 / . / y2020 / vision / extrinsics_calibration.cc
blob: 9f503733900958b20aff050921985e4664f4798e [file] [log] [blame]
#include "frc971/vision/extrinsics_calibration.h"
#include "Eigen/Dense"
#include "Eigen/Geometry"
#include "absl/flags/flag.h"
#include "absl/strings/str_format.h"
#include "aos/events/logging/log_reader.h"
#include "aos/init.h"
#include "aos/network/team_number.h"
#include "aos/time/time.h"
#include "aos/util/file.h"
#include "frc971/control_loops/quaternion_utils.h"
#include "frc971/vision/charuco_lib.h"
#include "frc971/vision/vision_generated.h"
#include "frc971/wpilib/imu_batch_generated.h"
#include "y2020/control_loops/superstructure/superstructure_status_generated.h"
ABSL_FLAG(std::string, pi, "pi-7971-2", "Pi name to calibrate.");
ABSL_FLAG(bool, plot, false, "Whether to plot the resulting data.");
ABSL_FLAG(bool, turret, false, "If true, the camera is on the turret");
ABSL_FLAG(std::string, base_intrinsics, "",
"Intrinsics to use for extrinsics calibration.");
namespace frc971::vision {
namespace chrono = std::chrono;
using aos::distributed_clock;
using aos::monotonic_clock;
void Main(int argc, char **argv) {
CalibrationData data;
{
// Now, accumulate all the data into the data object.
aos::logger::LogReader reader(
aos::logger::SortParts(aos::logger::FindLogs(argc, argv)));
aos::SimulatedEventLoopFactory factory(reader.configuration());
reader.Register(&factory);
CHECK(aos::configuration::MultiNode(reader.configuration()));
// Find the nodes we care about.
const aos::Node *const imu_node =
aos::configuration::GetNode(factory.configuration(), "imu");
const aos::Node *const roborio_node =
aos::configuration::GetNode(factory.configuration(), "roborio");
std::optional<uint16_t> pi_number =
aos::network::ParsePiOrOrinNumber(absl::GetFlag(FLAGS_pi));
CHECK(pi_number);
LOG(INFO) << "Pi " << *pi_number;
const aos::Node *const pi_node = aos::configuration::GetNode(
factory.configuration(), absl::StrCat("pi", *pi_number));
LOG(INFO) << "imu " << aos::FlatbufferToJson(imu_node);
LOG(INFO) << "roboRIO " << aos::FlatbufferToJson(roborio_node);
LOG(INFO) << "Pi " << aos::FlatbufferToJson(pi_node);
std::unique_ptr<aos::EventLoop> imu_event_loop =
factory.MakeEventLoop("calibration", imu_node);
std::unique_ptr<aos::EventLoop> roborio_event_loop =
factory.MakeEventLoop("calibration", roborio_node);
std::unique_ptr<aos::EventLoop> pi_event_loop =
factory.MakeEventLoop("calibration", pi_node);
aos::FlatbufferDetachedBuffer<calibration::CameraCalibration> intrinsics =
aos::JsonFileToFlatbuffer<calibration::CameraCalibration>(
absl::GetFlag(FLAGS_base_intrinsics));
// Now, hook Calibration up to everything.
Calibration extractor(&factory, pi_event_loop.get(), imu_event_loop.get(),
absl::GetFlag(FLAGS_pi), &intrinsics.message(),
TargetType::kCharuco, "/camera", &data);
if (absl::GetFlag(FLAGS_turret)) {
aos::NodeEventLoopFactory *roborio_factory =
factory.GetNodeEventLoopFactory(roborio_node->name()->string_view());
roborio_event_loop->MakeWatcher(
"/superstructure",
[roborio_factory, roborio_event_loop = roborio_event_loop.get(),
&data](const y2020::control_loops::superstructure::Status &status) {
data.AddTurret(
roborio_factory->ToDistributedClock(
roborio_event_loop->context().monotonic_event_time),
Eigen::Vector2d(status.turret()->position(),
status.turret()->velocity()));
});
}
factory.Run();
reader.Deregister();
}
LOG(INFO) << "Done with event_loop running";
// And now we have it, we can start processing it.
const Eigen::Quaternion<double> nominal_initial_orientation(
frc971::controls::ToQuaternionFromRotationVector(
Eigen::Vector3d(0.0, 0.0, M_PI)));
const Eigen::Quaternion<double> nominal_pivot_to_camera(
Eigen::AngleAxisd(-0.5 * M_PI, Eigen::Vector3d::UnitX()));
const Eigen::Quaternion<double> nominal_pivot_to_imu(
Eigen::AngleAxisd(0.0, Eigen::Vector3d::UnitX()));
const Eigen::Quaternion<double> nominal_board_to_world(
Eigen::AngleAxisd(0.5 * M_PI, Eigen::Vector3d::UnitX()));
Eigen::Matrix<double, 6, 1> nominal_initial_state =
Eigen::Matrix<double, 6, 1>::Zero();
// Set y value to -1 m (approx distance from imu to board/world
nominal_initial_state(1, 0) = -1.0;
CalibrationParameters calibration_parameters;
calibration_parameters.initial_orientation = nominal_initial_orientation;
calibration_parameters.pivot_to_camera = nominal_pivot_to_camera;
calibration_parameters.pivot_to_imu = nominal_pivot_to_imu;
calibration_parameters.board_to_world = nominal_board_to_world;
calibration_parameters.initial_state = nominal_initial_state;
if (data.turret_samples_size() > 0) {
LOG(INFO) << "Have turret, so using pivot setup";
calibration_parameters.has_pivot = true;
}
Solve(data, &calibration_parameters);
LOG(INFO) << "Nominal initial_orientation "
<< nominal_initial_orientation.coeffs().transpose();
LOG(INFO) << "Nominal pivot_to_camera "
<< nominal_pivot_to_camera.coeffs().transpose();
LOG(INFO) << "Nominal pivot_to_camera (rot-xyz) "
<< frc971::controls::ToRotationVectorFromQuaternion(
nominal_pivot_to_camera)
.transpose();
LOG(INFO) << "pivot_to_camera change "
<< frc971::controls::ToRotationVectorFromQuaternion(
calibration_parameters.pivot_to_camera *
nominal_pivot_to_camera.inverse())
.transpose();
LOG(INFO) << "Nominal pivot_to_imu "
<< nominal_pivot_to_imu.coeffs().transpose();
LOG(INFO) << "board_to_world delta "
<< frc971::controls::ToRotationVectorFromQuaternion(
calibration_parameters.board_to_world *
nominal_board_to_world.inverse())
.transpose();
if (absl::GetFlag(FLAGS_plot)) {
Plot(data, calibration_parameters);
}
}
} // namespace frc971::vision
int main(int argc, char **argv) {
aos::InitGoogle(&argc, &argv);
frc971::vision::Main(argc, argv);
}