px4-firmware/test/mavsdk_tests/autopilot_tester.cpp

784 lines
28 KiB
C++
Raw Normal View History

2020-03-17 12:15:34 -03:00
/****************************************************************************
*
2021-04-22 08:39:08 -03:00
* Copyright (c) 2021 PX4 Development Team. All rights reserved.
2020-03-17 12:15:34 -03:00
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
2019-10-02 15:14:18 -03:00
#include "autopilot_tester.h"
#include "math_helpers.h"
2019-10-02 15:14:18 -03:00
#include <iostream>
#include <future>
#include <thread>
#include <unistd.h>
New follow-me flight task rename follow_me_status to follow_target_status enable follow_target_estimator on skynode implement the responsiveness parameter: The responsiveness parameter should behave similarly to the previous follow-me implementation in navigator. The difference here is that there are now two separate gains for position and velocity fusion. The previous implemenation in navigator had no velocity fusion. Allow follow-me to be flown without RC SITL tests for follow-me flight task This includes: - Testing the setting for the follow-me angle - Testing that streaming position only or position and velocity measurements both work - Testing that RC override works Most of these tests are done with a simulated model of a point object that moves on a straight line. So nothing too spectacular. But it makes the test checks much easier. Since the estimator for the target actually checks new measurements and compares them to old ones, I also added random gausian noise to the measurements with a fixed seed for deterministic randomness. So repeated runs produce exactly the same results over and over. Half of the angles are still missing in MAVSDK. Need to create an upstream PR to add center left/right and rear left/right options. These and the corresponding SITL tests need to be implemented later. sitl: Increase position tolerance during follow-me Astro seems to barely exceed the current tolerance (4.3 !< 4.0) causing CI to fail. The point of the CI test is not to check the accuracy of the flight behaviour, but only the fact that the drone is doing the expected thing. So the exact value of this tolerance is not really important. follow-me: gimbal control in follow-me follow-me: create sub-routines in flight task class follow-me: use ground-dist for emergency ascent dist_bottom is only defined when a ground facing distance sensor exist. It's therefore better to use dist_ground instead, which has the distance to the home altitude if no distance sensor is available. As a consequence it will only be possible to use follow-me in a valley when the drone has a distance sensor. follow-me: point gimbal to the ground in 2D mode follow-me: another fuzzy msg handling for the estimator follow-me: bugfix in acceleration saturation limit follow-me: parameter for filter delay compensation mantis: dont use flow for terrain estimation follow-me: default responsiveness 0.5 -> 0.1 0.5 is way too jerky in real and simulated tests. flight_task: clarify comments for bottom distance follow-me: minor comment improvement follow-me: [debug] log emergency_ascent follow-me: [debug] log gimbal pitch follow-me: [debug] status values for follow-me estimator follow-me: setting for gimbal tracking mode follow-me: release gimbal control at destruction mavsdk: cosmetics :lipstick:
2021-07-20 04:11:17 -03:00
#include <cmath>
2019-10-02 15:14:18 -03:00
std::string connection_url {"udp://"};
std::optional<float> speed_factor {std::nullopt};
AutopilotTester::AutopilotTester() :
_real_time_report_thread([this]()
{
report_speed_factor();
})
{
}
AutopilotTester::~AutopilotTester()
{
_should_exit = true;
_real_time_report_thread.join();
}
2019-10-02 15:14:18 -03:00
void AutopilotTester::connect(const std::string uri)
{
2020-03-17 12:15:34 -03:00
ConnectionResult ret = _mavsdk.add_any_connection(uri);
REQUIRE(ret == ConnectionResult::Success);
2019-10-02 15:14:18 -03:00
std::cout << time_str() << "Waiting for system connect" << std::endl;
2020-03-17 12:15:34 -03:00
REQUIRE(poll_condition_with_timeout(
[this]() { return _mavsdk.systems().size() > 0; }, std::chrono::seconds(25)));
2019-10-02 15:14:18 -03:00
New follow-me flight task rename follow_me_status to follow_target_status enable follow_target_estimator on skynode implement the responsiveness parameter: The responsiveness parameter should behave similarly to the previous follow-me implementation in navigator. The difference here is that there are now two separate gains for position and velocity fusion. The previous implemenation in navigator had no velocity fusion. Allow follow-me to be flown without RC SITL tests for follow-me flight task This includes: - Testing the setting for the follow-me angle - Testing that streaming position only or position and velocity measurements both work - Testing that RC override works Most of these tests are done with a simulated model of a point object that moves on a straight line. So nothing too spectacular. But it makes the test checks much easier. Since the estimator for the target actually checks new measurements and compares them to old ones, I also added random gausian noise to the measurements with a fixed seed for deterministic randomness. So repeated runs produce exactly the same results over and over. Half of the angles are still missing in MAVSDK. Need to create an upstream PR to add center left/right and rear left/right options. These and the corresponding SITL tests need to be implemented later. sitl: Increase position tolerance during follow-me Astro seems to barely exceed the current tolerance (4.3 !< 4.0) causing CI to fail. The point of the CI test is not to check the accuracy of the flight behaviour, but only the fact that the drone is doing the expected thing. So the exact value of this tolerance is not really important. follow-me: gimbal control in follow-me follow-me: create sub-routines in flight task class follow-me: use ground-dist for emergency ascent dist_bottom is only defined when a ground facing distance sensor exist. It's therefore better to use dist_ground instead, which has the distance to the home altitude if no distance sensor is available. As a consequence it will only be possible to use follow-me in a valley when the drone has a distance sensor. follow-me: point gimbal to the ground in 2D mode follow-me: another fuzzy msg handling for the estimator follow-me: bugfix in acceleration saturation limit follow-me: parameter for filter delay compensation mantis: dont use flow for terrain estimation follow-me: default responsiveness 0.5 -> 0.1 0.5 is way too jerky in real and simulated tests. flight_task: clarify comments for bottom distance follow-me: minor comment improvement follow-me: [debug] log emergency_ascent follow-me: [debug] log gimbal pitch follow-me: [debug] status values for follow-me estimator follow-me: setting for gimbal tracking mode follow-me: release gimbal control at destruction mavsdk: cosmetics :lipstick:
2021-07-20 04:11:17 -03:00
auto system = get_system();
2019-10-02 15:14:18 -03:00
2020-03-17 12:15:34 -03:00
_action.reset(new Action(system));
_failure.reset(new Failure(system));
_info.reset(new Info(system));
2020-07-31 04:45:12 -03:00
_manual_control.reset(new ManualControl(system));
2020-03-17 12:15:34 -03:00
_mission.reset(new Mission(system));
_mission_raw.reset(new MissionRaw(system));
2020-03-17 12:15:34 -03:00
_offboard.reset(new Offboard(system));
_param.reset(new Param(system));
_telemetry.reset(new Telemetry(system));
2019-10-02 15:14:18 -03:00
}
void AutopilotTester::wait_until_ready()
{
std::cout << time_str() << "Waiting for system to be ready (system health ok & able to arm)" << std::endl;
// Wiat until the system is healthy
2020-03-17 12:15:34 -03:00
CHECK(poll_condition_with_timeout(
[this]() { return _telemetry->health_all_ok(); }, std::chrono::seconds(30)));
// Note: There is a known bug in MAVSDK (https://github.com/mavlink/MAVSDK/issues/1852),
// where `health_all_ok()` returning true doesn't actually mean vehicle is ready to accept
// global position estimate as valid (due to hysteresis). This needs to be fixed properly.
2019-10-02 15:14:18 -03:00
// However, this is mitigated by the `is_armable` check below as a side effect, since
// when the vehicle considers global position to be valid, it will then allow arming
// Wait until we can arm
2020-03-17 12:15:34 -03:00
CHECK(poll_condition_with_timeout(
[this]() { return _telemetry->health().is_armable; }, std::chrono::seconds(20)));
}
void AutopilotTester::store_home()
{
2020-03-17 12:15:34 -03:00
request_ground_truth();
std::cout << time_str() << "Waiting to get home position" << std::endl;
CHECK(poll_condition_with_timeout(
[this]() {
_home = _telemetry->ground_truth();
return std::isfinite(_home.latitude_deg) && std::isfinite(_home.longitude_deg);
}, std::chrono::seconds(10)));
}
void AutopilotTester::check_home_within(float acceptance_radius_m)
{
2020-03-17 12:15:34 -03:00
CHECK(ground_truth_horizontal_position_close_to(_home, acceptance_radius_m));
}
2020-07-31 04:45:12 -03:00
void AutopilotTester::check_home_not_within(float min_distance_m)
{
CHECK(ground_truth_horizontal_position_far_from(_home, min_distance_m));
}
2019-10-02 15:14:18 -03:00
void AutopilotTester::set_takeoff_altitude(const float altitude_m)
{
CHECK(Action::Result::Success == _action->set_takeoff_altitude(altitude_m));
2020-03-17 12:15:34 -03:00
const auto result = _action->get_takeoff_altitude();
CHECK(result.first == Action::Result::Success);
2020-03-17 12:15:34 -03:00
CHECK(result.second == Approx(altitude_m));
2019-10-02 15:14:18 -03:00
}
2021-11-26 11:52:14 -04:00
void AutopilotTester::set_rtl_altitude(const float altitude_m)
{
CHECK(Action::Result::Success == _action->set_return_to_launch_altitude(altitude_m));
const auto result = _action->get_return_to_launch_altitude();
CHECK(result.first == Action::Result::Success);
CHECK(result.second == Approx(altitude_m));
}
void AutopilotTester::set_height_source(AutopilotTester::HeightSource height_source)
{
switch (height_source) {
case HeightSource::Baro:
CHECK(_param->set_param_int("EKF2_HGT_REF", 0) == Param::Result::Success);
break;
case HeightSource::Gps:
CHECK(_param->set_param_int("EKF2_HGT_REF", 1) == Param::Result::Success);
}
}
void AutopilotTester::set_rc_loss_exception(AutopilotTester::RcLossException mask)
{
switch (mask) {
case RcLossException::Mission:
CHECK(_param->set_param_int("COM_RCL_EXCEPT", 1 << 0) == Param::Result::Success);
break;
case RcLossException::Hold:
CHECK(_param->set_param_int("COM_RCL_EXCEPT", 1 << 1) == Param::Result::Success);
break;
case RcLossException::Offboard:
CHECK(_param->set_param_int("COM_RCL_EXCEPT", 1 << 2) == Param::Result::Success);
}
}
2019-10-02 15:14:18 -03:00
void AutopilotTester::arm()
{
2020-03-17 12:15:34 -03:00
const auto result = _action->arm();
REQUIRE(result == Action::Result::Success);
2019-10-02 15:14:18 -03:00
}
void AutopilotTester::takeoff()
{
2020-03-17 12:15:34 -03:00
const auto result = _action->takeoff();
REQUIRE(result == Action::Result::Success);
2019-10-02 15:14:18 -03:00
}
void AutopilotTester::land()
{
2020-03-17 12:15:34 -03:00
const auto result = _action->land();
REQUIRE(result == Action::Result::Success);
2019-10-02 15:14:18 -03:00
}
void AutopilotTester::transition_to_fixedwing()
{
2020-03-17 12:15:34 -03:00
const auto result = _action->transition_to_fixedwing();
REQUIRE(result == Action::Result::Success);
}
void AutopilotTester::transition_to_multicopter()
{
2020-03-17 12:15:34 -03:00
const auto result = _action->transition_to_multicopter();
REQUIRE(result == Action::Result::Success);
}
2020-05-05 06:42:06 -03:00
void AutopilotTester::wait_until_disarmed(std::chrono::seconds timeout_duration)
2019-10-02 15:14:18 -03:00
{
2020-03-17 12:15:34 -03:00
REQUIRE(poll_condition_with_timeout(
2020-05-05 06:42:06 -03:00
[this]() { return !_telemetry->armed(); }, timeout_duration));
2019-10-02 15:14:18 -03:00
}
void AutopilotTester::wait_until_hovering()
{
wait_for_landed_state(Telemetry::LandedState::InAir, std::chrono::seconds(45));
2019-10-02 15:14:18 -03:00
}
2021-11-26 11:52:14 -04:00
void AutopilotTester::wait_until_altitude(float rel_altitude_m, std::chrono::seconds timeout)
{
auto prom = std::promise<void> {};
auto fut = prom.get_future();
_telemetry->subscribe_position([&prom, rel_altitude_m, this](Telemetry::Position new_position) {
if (fabs(rel_altitude_m - new_position.relative_altitude_m) <= 0.5) {
_telemetry->subscribe_position(nullptr);
prom.set_value();
}
});
REQUIRE(fut.wait_for(timeout) == std::future_status::ready);
}
2019-10-02 15:14:18 -03:00
void AutopilotTester::prepare_square_mission(MissionOptions mission_options)
{
2020-03-17 12:15:34 -03:00
const auto ct = get_coordinate_transformation();
2019-10-02 15:14:18 -03:00
Mission::MissionPlan mission_plan {};
mission_plan.mission_items.push_back(create_mission_item({mission_options.leg_length_m, 0.}, mission_options, ct));
mission_plan.mission_items.push_back(create_mission_item({mission_options.leg_length_m, mission_options.leg_length_m},
mission_options, ct));
mission_plan.mission_items.push_back(create_mission_item({0., mission_options.leg_length_m}, mission_options, ct));
2019-10-02 15:14:18 -03:00
2020-03-17 12:15:34 -03:00
_mission->set_return_to_launch_after_mission(mission_options.rtl_at_end);
2019-10-02 15:14:18 -03:00
REQUIRE(_mission->upload_mission(mission_plan) == Mission::Result::Success);
2019-10-02 15:14:18 -03:00
}
2020-07-09 12:36:24 -03:00
void AutopilotTester::prepare_straight_mission(MissionOptions mission_options)
{
const auto ct = get_coordinate_transformation();
Mission::MissionPlan mission_plan {};
mission_plan.mission_items.push_back(create_mission_item({0, 0.}, mission_options, ct));
mission_plan.mission_items.push_back(create_mission_item({mission_options.leg_length_m, 0}, mission_options, ct));
mission_plan.mission_items.push_back(create_mission_item({2 * mission_options.leg_length_m, 0}, mission_options, ct));
mission_plan.mission_items.push_back(create_mission_item({3 * mission_options.leg_length_m, 0}, mission_options, ct));
mission_plan.mission_items.push_back(create_mission_item({4 * mission_options.leg_length_m, 0}, mission_options, ct));
_mission->set_return_to_launch_after_mission(mission_options.rtl_at_end);
REQUIRE(_mission->upload_mission(mission_plan) == Mission::Result::Success);
2020-07-09 12:36:24 -03:00
}
2019-10-02 15:14:18 -03:00
void AutopilotTester::execute_mission()
{
2020-03-17 12:15:34 -03:00
std::promise<void> prom;
auto fut = prom.get_future();
2019-10-02 15:14:18 -03:00
REQUIRE(poll_condition_with_timeout(
[this]() { return _mission->start_mission() == Mission::Result::Success; }, std::chrono::seconds(3)));
2019-10-02 15:14:18 -03:00
2020-03-17 12:15:34 -03:00
// TODO: Adapt time limit based on mission size, flight speed, sim speed factor, etc.
wait_for_mission_finished(std::chrono::seconds(90));
2019-10-02 15:14:18 -03:00
}
void AutopilotTester::execute_mission_and_lose_gps()
{
CHECK(_param->set_param_int("SYS_FAILURE_EN", 1) == Param::Result::Success);
start_and_wait_for_first_mission_item();
CHECK(_failure->inject(Failure::FailureUnit::SensorGps, Failure::FailureType::Off, 0) == Failure::Result::Success);
// We expect that a blind land is performed.
wait_for_flight_mode(Telemetry::FlightMode::Land, std::chrono::seconds(30));
}
void AutopilotTester::execute_mission_and_lose_mag()
{
CHECK(_param->set_param_int("SYS_FAILURE_EN", 1) == Param::Result::Success);
start_and_wait_for_first_mission_item();
CHECK(_failure->inject(Failure::FailureUnit::SensorMag, Failure::FailureType::Off, 0) == Failure::Result::Success);
// We except the mission to continue without mag just fine.
REQUIRE(poll_condition_with_timeout(
[this]() {
auto progress = _mission->mission_progress();
return progress.current == progress.total;
}, std::chrono::seconds(90)));
}
void AutopilotTester::execute_mission_and_lose_baro()
{
CHECK(_param->set_param_int("SYS_FAILURE_EN", 1) == Param::Result::Success);
start_and_wait_for_first_mission_item();
CHECK(_failure->inject(Failure::FailureUnit::SensorBaro, Failure::FailureType::Off, 0) == Failure::Result::Success);
// We except the mission to continue without baro just fine.
REQUIRE(poll_condition_with_timeout(
[this]() {
auto progress = _mission->mission_progress();
return progress.current == progress.total;
}, std::chrono::seconds(90)));
2020-06-26 09:48:53 -03:00
}
void AutopilotTester::execute_mission_and_get_baro_stuck()
{
CHECK(_param->set_param_int("SYS_FAILURE_EN", 1) == Param::Result::Success);
start_and_wait_for_first_mission_item();
CHECK(_failure->inject(Failure::FailureUnit::SensorBaro, Failure::FailureType::Stuck, 0) == Failure::Result::Success);
2020-06-26 09:48:53 -03:00
// We except the mission to continue with a stuck baro just fine.
REQUIRE(poll_condition_with_timeout(
[this]() {
auto progress = _mission->mission_progress();
return progress.current == progress.total;
}, std::chrono::seconds(90)));
}
2020-06-26 11:43:51 -03:00
void AutopilotTester::execute_mission_and_get_mag_stuck()
{
CHECK(_param->set_param_int("SYS_FAILURE_EN", 1) == Param::Result::Success);
start_and_wait_for_first_mission_item();
2020-06-26 11:43:51 -03:00
CHECK(_failure->inject(Failure::FailureUnit::SensorMag, Failure::FailureType::Stuck, 0) == Failure::Result::Success);
2020-06-26 11:43:51 -03:00
// We except the mission to continue with a stuck mag just fine.
REQUIRE(poll_condition_with_timeout(
[this]() {
auto progress = _mission->mission_progress();
return progress.current == progress.total;
}, std::chrono::seconds(120)));
2020-06-26 11:43:51 -03:00
}
CoordinateTransformation AutopilotTester::get_coordinate_transformation()
2019-10-02 15:14:18 -03:00
{
const auto home = _telemetry->home();
2020-03-17 12:15:34 -03:00
CHECK(std::isfinite(home.latitude_deg));
CHECK(std::isfinite(home.longitude_deg));
return CoordinateTransformation({home.latitude_deg, home.longitude_deg});
2019-10-02 15:14:18 -03:00
}
Mission::MissionItem AutopilotTester::create_mission_item(
2020-03-17 12:15:34 -03:00
const CoordinateTransformation::LocalCoordinate &local_coordinate,
const MissionOptions &mission_options,
const CoordinateTransformation &ct)
2019-10-02 15:14:18 -03:00
{
auto mission_item = Mission::MissionItem{};
2020-03-17 12:15:34 -03:00
const auto pos_north = ct.global_from_local(local_coordinate);
mission_item.latitude_deg = pos_north.latitude_deg;
mission_item.longitude_deg = pos_north.longitude_deg;
mission_item.relative_altitude_m = mission_options.relative_altitude_m;
2020-07-09 12:36:24 -03:00
mission_item.is_fly_through = mission_options.fly_through;
2020-03-17 12:15:34 -03:00
return mission_item;
}
void AutopilotTester::load_qgc_mission_raw_and_move_here(const std::string &plan_file)
{
auto import_result = _mission_raw->import_qgroundcontrol_mission(plan_file);
REQUIRE(import_result.first == MissionRaw::Result::Success);
move_mission_raw_here(import_result.second.mission_items);
REQUIRE(_mission_raw->upload_mission(import_result.second.mission_items) == MissionRaw::Result::Success);
}
void AutopilotTester::execute_mission_raw()
{
REQUIRE(_mission->start_mission() == Mission::Result::Success);
// TODO: Adapt time limit based on mission size, flight speed, sim speed factor, etc.
wait_for_mission_raw_finished(std::chrono::seconds(120));
}
void AutopilotTester::execute_rtl()
{
REQUIRE(Action::Result::Success == _action->return_to_launch());
}
2021-11-26 11:52:14 -04:00
void AutopilotTester::execute_land()
{
REQUIRE(Action::Result::Success == _action->land());
}
void AutopilotTester::offboard_goto(const Offboard::PositionNedYaw &target, float acceptance_radius_m,
2020-03-17 12:15:34 -03:00
std::chrono::seconds timeout_duration)
{
2020-03-17 12:15:34 -03:00
_offboard->set_position_ned(target);
REQUIRE(_offboard->start() == Offboard::Result::Success);
2020-03-17 12:15:34 -03:00
CHECK(poll_condition_with_timeout(
[ = ]() { return estimated_position_close_to(target, acceptance_radius_m); }, timeout_duration));
std::cout << time_str() << "Target position reached" << std::endl;
}
void AutopilotTester::check_mission_item_speed_above(int item_index, float min_speed_m_s)
2020-07-09 12:36:24 -03:00
{
_telemetry->set_rate_velocity_ned(10);
_telemetry->subscribe_velocity_ned([item_index, min_speed_m_s, this](Telemetry::VelocityNed velocity) {
2020-07-09 12:36:24 -03:00
float horizontal = std::hypot(velocity.north_m_s, velocity.east_m_s);
auto progress = _mission->mission_progress();
if (progress.current == item_index) {
CHECK(horizontal > min_speed_m_s);
2020-07-09 12:36:24 -03:00
}
});
}
2020-07-31 04:45:12 -03:00
void AutopilotTester::fly_forward_in_posctl()
{
2020-08-05 13:20:58 -03:00
const unsigned manual_control_rate_hz = 50;
2020-07-31 04:45:12 -03:00
// Send something to make sure RC is available.
for (unsigned i = 0; i < 1 * manual_control_rate_hz; ++i) {
CHECK(_manual_control->set_manual_control_input(0.f, 0.f, 0.5f, 0.f) == ManualControl::Result::Success);
sleep_for(std::chrono::milliseconds(1000 / manual_control_rate_hz));
}
CHECK(_manual_control->start_position_control() == ManualControl::Result::Success);
// Climb up for 20 seconds
for (unsigned i = 0; i < 20 * manual_control_rate_hz; ++i) {
2020-07-31 04:45:12 -03:00
CHECK(_manual_control->set_manual_control_input(0.f, 0.f, 1.f, 0.f) == ManualControl::Result::Success);
sleep_for(std::chrono::milliseconds(1000 / manual_control_rate_hz));
2020-07-31 04:45:12 -03:00
}
// Fly forward for 60 seconds
for (unsigned i = 0; i < 60 * manual_control_rate_hz; ++i) {
2020-07-31 04:45:12 -03:00
CHECK(_manual_control->set_manual_control_input(0.5f, 0.f, 0.5f, 0.f) == ManualControl::Result::Success);
sleep_for(std::chrono::milliseconds(1000 / manual_control_rate_hz));
2020-07-31 04:45:12 -03:00
}
// Descend until disarmed
for (unsigned i = 0; i < 60 * manual_control_rate_hz; ++i) {
2020-07-31 04:45:12 -03:00
CHECK(_manual_control->set_manual_control_input(0.f, 0.f, 0.0f, 0.f) == ManualControl::Result::Success);
sleep_for(std::chrono::milliseconds(1000 / manual_control_rate_hz));
2020-07-31 04:45:12 -03:00
if (!_telemetry->in_air()) {
break;
}
}
}
void AutopilotTester::fly_forward_in_altctl()
{
const unsigned manual_control_rate_hz = 50;
2020-07-31 04:45:12 -03:00
// Send something to make sure RC is available.
for (unsigned i = 0; i < 1 * manual_control_rate_hz; ++i) {
CHECK(_manual_control->set_manual_control_input(0.f, 0.f, 0.5f, 0.f) == ManualControl::Result::Success);
sleep_for(std::chrono::milliseconds(1000 / manual_control_rate_hz));
}
2020-07-31 04:45:12 -03:00
CHECK(_manual_control->start_altitude_control() == ManualControl::Result::Success);
2020-07-31 04:45:12 -03:00
// Climb up for 20 seconds
for (unsigned i = 0; i < 20 * manual_control_rate_hz; ++i) {
2020-07-31 04:45:12 -03:00
CHECK(_manual_control->set_manual_control_input(0.f, 0.f, 1.f, 0.f) == ManualControl::Result::Success);
sleep_for(std::chrono::milliseconds(1000 / manual_control_rate_hz));
2020-07-31 04:45:12 -03:00
}
// Fly forward for 60 seconds
for (unsigned i = 0; i < 60 * manual_control_rate_hz; ++i) {
2020-07-31 04:45:12 -03:00
CHECK(_manual_control->set_manual_control_input(0.5f, 0.f, 0.5f, 0.f) == ManualControl::Result::Success);
sleep_for(std::chrono::milliseconds(1000 / manual_control_rate_hz));
2020-07-31 04:45:12 -03:00
}
// Descend until disarmed
for (unsigned i = 0; i < 60 * manual_control_rate_hz; ++i) {
2020-07-31 04:45:12 -03:00
CHECK(_manual_control->set_manual_control_input(0.f, 0.f, 0.0f, 0.f) == ManualControl::Result::Success);
sleep_for(std::chrono::milliseconds(1000 / manual_control_rate_hz));
2020-07-31 04:45:12 -03:00
if (!_telemetry->in_air()) {
break;
}
}
}
2021-11-26 11:52:14 -04:00
void AutopilotTester::start_checking_altitude(const float max_deviation_m)
{
std::array<float, 3> initial_position = get_current_position_ned();
float target_altitude = initial_position[2];
_telemetry->subscribe_position([target_altitude, max_deviation_m, this](Telemetry::Position new_position) {
const float current_deviation = fabs((-target_altitude) - new_position.relative_altitude_m);
CHECK(current_deviation <= max_deviation_m);
});
}
void AutopilotTester::stop_checking_altitude()
{
_telemetry->subscribe_position(nullptr);
}
void AutopilotTester::check_tracks_mission(float corridor_radius_m)
{
auto mission = _mission->download_mission();
CHECK(mission.first == Mission::Result::Success);
std::vector<Mission::MissionItem> mission_items = mission.second.mission_items;
auto ct = get_coordinate_transformation();
_telemetry->set_rate_position_velocity_ned(5);
_telemetry->subscribe_position_velocity_ned([ct, mission_items, corridor_radius_m,
this](Telemetry::PositionVelocityNed position_velocity_ned) {
auto progress = _mission->mission_progress();
if (progress.current > 0 && progress.current < progress.total) {
// Get shortest distance of current position to 3D line between previous and next waypoint
std::array<float, 3> current { position_velocity_ned.position.north_m,
position_velocity_ned.position.east_m,
position_velocity_ned.position.down_m };
std::array<float, 3> wp_prev = get_local_mission_item<float>(mission_items[progress.current - 1], ct);
std::array<float, 3> wp_next = get_local_mission_item<float>(mission_items[progress.current], ct);
float distance_to_trajectory = point_to_line_distance(current, wp_prev, wp_next);
CHECK(distance_to_trajectory < corridor_radius_m);
}
});
}
New follow-me flight task rename follow_me_status to follow_target_status enable follow_target_estimator on skynode implement the responsiveness parameter: The responsiveness parameter should behave similarly to the previous follow-me implementation in navigator. The difference here is that there are now two separate gains for position and velocity fusion. The previous implemenation in navigator had no velocity fusion. Allow follow-me to be flown without RC SITL tests for follow-me flight task This includes: - Testing the setting for the follow-me angle - Testing that streaming position only or position and velocity measurements both work - Testing that RC override works Most of these tests are done with a simulated model of a point object that moves on a straight line. So nothing too spectacular. But it makes the test checks much easier. Since the estimator for the target actually checks new measurements and compares them to old ones, I also added random gausian noise to the measurements with a fixed seed for deterministic randomness. So repeated runs produce exactly the same results over and over. Half of the angles are still missing in MAVSDK. Need to create an upstream PR to add center left/right and rear left/right options. These and the corresponding SITL tests need to be implemented later. sitl: Increase position tolerance during follow-me Astro seems to barely exceed the current tolerance (4.3 !< 4.0) causing CI to fail. The point of the CI test is not to check the accuracy of the flight behaviour, but only the fact that the drone is doing the expected thing. So the exact value of this tolerance is not really important. follow-me: gimbal control in follow-me follow-me: create sub-routines in flight task class follow-me: use ground-dist for emergency ascent dist_bottom is only defined when a ground facing distance sensor exist. It's therefore better to use dist_ground instead, which has the distance to the home altitude if no distance sensor is available. As a consequence it will only be possible to use follow-me in a valley when the drone has a distance sensor. follow-me: point gimbal to the ground in 2D mode follow-me: another fuzzy msg handling for the estimator follow-me: bugfix in acceleration saturation limit follow-me: parameter for filter delay compensation mantis: dont use flow for terrain estimation follow-me: default responsiveness 0.5 -> 0.1 0.5 is way too jerky in real and simulated tests. flight_task: clarify comments for bottom distance follow-me: minor comment improvement follow-me: [debug] log emergency_ascent follow-me: [debug] log gimbal pitch follow-me: [debug] status values for follow-me estimator follow-me: setting for gimbal tracking mode follow-me: release gimbal control at destruction mavsdk: cosmetics :lipstick:
2021-07-20 04:11:17 -03:00
void AutopilotTester::check_current_altitude(float target_rel_altitude_m, float max_distance_m)
{
CHECK(std::abs(_telemetry->position().relative_altitude_m - target_rel_altitude_m) <= max_distance_m);
}
2021-11-26 11:52:14 -04:00
std::array<float, 3> AutopilotTester::get_current_position_ned()
{
mavsdk::Telemetry::PositionVelocityNed position_velocity_ned = _telemetry->position_velocity_ned();
std::array<float, 3> position_ned{position_velocity_ned.position.north_m, position_velocity_ned.position.east_m, position_velocity_ned.position.down_m};
return position_ned;
}
void AutopilotTester::offboard_land()
{
Offboard::VelocityNedYaw land_velocity;
2020-03-17 12:15:34 -03:00
land_velocity.north_m_s = 0.0f;
land_velocity.east_m_s = 0.0f;
land_velocity.down_m_s = 1.0f;
land_velocity.yaw_deg = 0.0f;
_offboard->set_velocity_ned(land_velocity);
}
bool AutopilotTester::estimated_position_close_to(const Offboard::PositionNedYaw &target_pos, float acceptance_radius_m)
{
Telemetry::PositionNed est_pos = _telemetry->position_velocity_ned().position;
const float distance_m = std::sqrt(sq(est_pos.north_m - target_pos.north_m) +
sq(est_pos.east_m - target_pos.east_m) +
sq(est_pos.down_m - target_pos.down_m));
const bool pass = distance_m < acceptance_radius_m;
if (!pass) {
std::cout << time_str() << "distance: " << distance_m << ", " << "acceptance: " << acceptance_radius_m << std::endl;
}
return pass;
}
bool AutopilotTester::estimated_horizontal_position_close_to(const Offboard::PositionNedYaw &target_pos,
2020-03-17 12:15:34 -03:00
float acceptance_radius_m)
{
Telemetry::PositionNed est_pos = _telemetry->position_velocity_ned().position;
2020-03-17 12:15:34 -03:00
return sq(est_pos.north_m - target_pos.north_m) +
sq(est_pos.east_m - target_pos.east_m) < sq(acceptance_radius_m);
}
void AutopilotTester::request_ground_truth()
{
CHECK(_telemetry->set_rate_ground_truth(15) == Telemetry::Result::Success);
}
2020-03-17 12:15:34 -03:00
bool AutopilotTester::ground_truth_horizontal_position_close_to(const Telemetry::GroundTruth &target_pos,
float acceptance_radius_m)
{
2020-03-17 12:15:34 -03:00
CHECK(std::isfinite(target_pos.latitude_deg));
CHECK(std::isfinite(target_pos.longitude_deg));
using GlobalCoordinate = CoordinateTransformation::GlobalCoordinate;
using LocalCoordinate = CoordinateTransformation::LocalCoordinate;
CoordinateTransformation ct(GlobalCoordinate{target_pos.latitude_deg, target_pos.longitude_deg});
Telemetry::GroundTruth current_pos = _telemetry->ground_truth();
CHECK(std::isfinite(current_pos.latitude_deg));
CHECK(std::isfinite(current_pos.longitude_deg));
GlobalCoordinate global_current;
global_current.latitude_deg = current_pos.latitude_deg;
global_current.longitude_deg = current_pos.longitude_deg;
LocalCoordinate local_pos = ct.local_from_global(global_current);
2020-07-31 04:45:12 -03:00
const double distance_m = sqrt(sq(local_pos.north_m) + sq(local_pos.east_m));
const bool pass = distance_m < acceptance_radius_m;
if (!pass) {
std::cout << time_str() << "target_pos.lat: " << target_pos.latitude_deg << std::endl;
std::cout << time_str() << "target_pos.lon: " << target_pos.longitude_deg << std::endl;
std::cout << time_str() << "current.lat: " << current_pos.latitude_deg << std::endl;
std::cout << time_str() << "current.lon: " << current_pos.longitude_deg << std::endl;
std::cout << time_str() << "Distance: " << distance_m << std::endl;
std::cout << time_str() << "Acceptance radius: " << acceptance_radius_m << std::endl;
}
return pass;
}
2020-07-31 04:45:12 -03:00
bool AutopilotTester::ground_truth_horizontal_position_far_from(const Telemetry::GroundTruth &target_pos,
float min_distance_m)
{
CHECK(std::isfinite(target_pos.latitude_deg));
CHECK(std::isfinite(target_pos.longitude_deg));
using GlobalCoordinate = CoordinateTransformation::GlobalCoordinate;
using LocalCoordinate = CoordinateTransformation::LocalCoordinate;
CoordinateTransformation ct(GlobalCoordinate{target_pos.latitude_deg, target_pos.longitude_deg});
Telemetry::GroundTruth current_pos = _telemetry->ground_truth();
CHECK(std::isfinite(current_pos.latitude_deg));
CHECK(std::isfinite(current_pos.longitude_deg));
GlobalCoordinate global_current;
global_current.latitude_deg = current_pos.latitude_deg;
global_current.longitude_deg = current_pos.longitude_deg;
LocalCoordinate local_pos = ct.local_from_global(global_current);
const double distance_m = sqrt(sq(local_pos.north_m) + sq(local_pos.east_m));
const bool pass = distance_m > min_distance_m;
if (!pass) {
std::cout << time_str() << "target_pos.lat: " << target_pos.latitude_deg << std::endl;
std::cout << time_str() << "target_pos.lon: " << target_pos.longitude_deg << std::endl;
std::cout << time_str() << "current.lat: " << current_pos.latitude_deg << std::endl;
std::cout << time_str() << "current.lon: " << current_pos.longitude_deg << std::endl;
std::cout << time_str() << "Distance: " << distance_m << std::endl;
std::cout << time_str() << "Min distance: " << min_distance_m << std::endl;
2020-07-31 04:45:12 -03:00
}
return pass;
}
void AutopilotTester::start_and_wait_for_first_mission_item()
{
auto prom = std::promise<void> {};
auto fut = prom.get_future();
_mission->subscribe_mission_progress([&prom, this](Mission::MissionProgress progress) {
std::cout << time_str() << "Progress: " << progress.current << "/" << progress.total << std::endl;
if (progress.current >= 1) {
_mission->subscribe_mission_progress(nullptr);
prom.set_value();
}
});
REQUIRE(_mission->start_mission() == Mission::Result::Success);
REQUIRE(fut.wait_for(std::chrono::seconds(60)) == std::future_status::ready);
}
void AutopilotTester::wait_for_flight_mode(Telemetry::FlightMode flight_mode, std::chrono::seconds timeout)
{
auto prom = std::promise<void> {};
auto fut = prom.get_future();
_telemetry->subscribe_flight_mode([&prom, flight_mode, this](Telemetry::FlightMode new_flight_mode) {
if (new_flight_mode == flight_mode) {
_telemetry->subscribe_flight_mode(nullptr);
prom.set_value();
}
});
REQUIRE(fut.wait_for(timeout) == std::future_status::ready);
}
void AutopilotTester::wait_for_landed_state(Telemetry::LandedState landed_state, std::chrono::seconds timeout)
{
auto prom = std::promise<void> {};
auto fut = prom.get_future();
_telemetry->subscribe_landed_state([&prom, landed_state, this](Telemetry::LandedState new_landed_state) {
if (new_landed_state == landed_state) {
_telemetry->subscribe_landed_state(nullptr);
2021-11-26 11:52:14 -04:00
prom.set_value();
}
});
REQUIRE(fut.wait_for(timeout) == std::future_status::ready);
}
void AutopilotTester::wait_until_speed_lower_than(float speed, std::chrono::seconds timeout)
{
auto prom = std::promise<void> {};
auto fut = prom.get_future();
_telemetry->subscribe_position_velocity_ned([&prom, speed, this](Telemetry::PositionVelocityNed position_velocity_ned) {
std::array<float, 3> current_velocity;
current_velocity[0] = position_velocity_ned.velocity.north_m_s;
current_velocity[1] = position_velocity_ned.velocity.east_m_s;
current_velocity[2] = position_velocity_ned.velocity.down_m_s;
const float current_speed = norm(current_velocity);
if (current_speed <= speed) {
_telemetry->subscribe_position_velocity_ned(nullptr);
prom.set_value();
}
});
REQUIRE(fut.wait_for(timeout) == std::future_status::ready);
}
void AutopilotTester::wait_for_mission_finished(std::chrono::seconds timeout)
{
auto prom = std::promise<void> {};
auto fut = prom.get_future();
_mission->subscribe_mission_progress([&prom, this](Mission::MissionProgress progress) {
if (progress.current == progress.total) {
_mission->subscribe_mission_progress(nullptr);
prom.set_value();
}
});
REQUIRE(fut.wait_for(timeout) == std::future_status::ready);
}
void AutopilotTester::wait_for_mission_raw_finished(std::chrono::seconds timeout)
{
auto prom = std::promise<void> {};
auto fut = prom.get_future();
_mission_raw->subscribe_mission_progress([&prom, this](MissionRaw::MissionProgress progress) {
if (progress.current == progress.total) {
_mission_raw->subscribe_mission_progress(nullptr);
prom.set_value();
}
});
REQUIRE(fut.wait_for(timeout) == std::future_status::ready);
}
void AutopilotTester::move_mission_raw_here(std::vector<MissionRaw::MissionItem> &mission_items)
{
const auto position = _telemetry->position();
REQUIRE(std::isfinite(position.latitude_deg));
REQUIRE(std::isfinite(position.longitude_deg));
auto offset_x = mission_items[0].x - static_cast<int32_t>(1e7 * position.latitude_deg);
2021-04-22 08:39:08 -03:00
auto offset_y = mission_items[0].y - static_cast<int32_t>(1e7 * position.longitude_deg);
for (auto &item : mission_items) {
if (item.frame == 3) { // MAV_FRAME_GLOBAL_RELATIVE_ALT
item.x -= offset_x;
}
item.y -= offset_y;
}
}
void AutopilotTester::report_speed_factor()
{
// We check the exit flag more often than the speed factor.
unsigned counter = 0;
while (!_should_exit) {
if (counter++ % 10 == 0) {
if (_info != nullptr) {
std::cout << "Current speed factor: " << _info->get_speed_factor().second ;
if (speed_factor.has_value()) {
std::cout << " (set: " << speed_factor.value() << ')';
}
std::cout << std::endl;
}
}
std::this_thread::sleep_for(std::chrono::milliseconds(100));
}
}