/* This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include "AP_Follow_config.h" #if AP_FOLLOW_ENABLED #include #include "AP_Follow.h" #include #include #include #include #include #include extern const AP_HAL::HAL& hal; #define AP_FOLLOW_TIMEOUT_MS 3000 // position estimate timeout after 1 second #define AP_FOLLOW_SYSID_TIMEOUT_MS 10000 // forget sysid we are following if we have not heard from them in 10 seconds #define AP_FOLLOW_OFFSET_TYPE_NED 0 // offsets are in north-east-down frame #define AP_FOLLOW_OFFSET_TYPE_RELATIVE 1 // offsets are relative to lead vehicle's heading #define AP_FOLLOW_ALTITUDE_TYPE_RELATIVE 1 // relative altitude is used by default #define AP_FOLLOW_POS_P_DEFAULT 0.1f // position error gain default #if APM_BUILD_TYPE(APM_BUILD_ArduPlane) #define AP_FOLLOW_ALT_TYPE_DEFAULT 0 #else #define AP_FOLLOW_ALT_TYPE_DEFAULT AP_FOLLOW_ALTITUDE_TYPE_RELATIVE #endif AP_Follow *AP_Follow::_singleton; // table of user settable parameters const AP_Param::GroupInfo AP_Follow::var_info[] = { // @Param: _ENABLE // @DisplayName: Follow enable/disable // @Description: Enabled/disable following a target // @Values: 0:Disabled,1:Enabled // @User: Standard AP_GROUPINFO_FLAGS("_ENABLE", 1, AP_Follow, _enabled, 0, AP_PARAM_FLAG_ENABLE), // 2 is reserved for TYPE parameter // @Param: _SYSID // @DisplayName: Follow target's mavlink system id // @Description: Follow target's mavlink system id // @Range: 0 255 // @User: Standard AP_GROUPINFO("_SYSID", 3, AP_Follow, _sysid, 0), // 4 is reserved for MARGIN parameter // @Param: _DIST_MAX // @DisplayName: Follow distance maximum // @Description: Follow distance maximum. targets further than this will be ignored // @Units: m // @Range: 1 1000 // @User: Standard AP_GROUPINFO("_DIST_MAX", 5, AP_Follow, _dist_max, 100), // @Param: _OFS_TYPE // @DisplayName: Follow offset type // @Description: Follow offset type // @Values: 0:North-East-Down, 1:Relative to lead vehicle heading // @User: Standard AP_GROUPINFO("_OFS_TYPE", 6, AP_Follow, _offset_type, AP_FOLLOW_OFFSET_TYPE_NED), // @Param: _OFS_X // @DisplayName: Follow offsets in meters north/forward // @Description: Follow offsets in meters north/forward. If positive, this vehicle fly ahead or north of lead vehicle. Depends on FOLL_OFS_TYPE // @Range: -100 100 // @Units: m // @Increment: 1 // @User: Standard // @Param: _OFS_Y // @DisplayName: Follow offsets in meters east/right // @Description: Follow offsets in meters east/right. If positive, this vehicle will fly to the right or east of lead vehicle. Depends on FOLL_OFS_TYPE // @Range: -100 100 // @Units: m // @Increment: 1 // @User: Standard // @Param: _OFS_Z // @DisplayName: Follow offsets in meters down // @Description: Follow offsets in meters down. If positive, this vehicle will fly below the lead vehicle // @Range: -100 100 // @Units: m // @Increment: 1 // @User: Standard AP_GROUPINFO("_OFS", 7, AP_Follow, _offset, 0), #if !(APM_BUILD_TYPE(APM_BUILD_Rover)) // @Param: _YAW_BEHAVE // @DisplayName: Follow yaw behaviour // @Description: Follow yaw behaviour // @Values: 0:None,1:Face Lead Vehicle,2:Same as Lead vehicle,3:Direction of Flight // @User: Standard AP_GROUPINFO("_YAW_BEHAVE", 8, AP_Follow, _yaw_behave, 1), #endif // @Param: _POS_P // @DisplayName: Follow position error P gain // @Description: Follow position error P gain. Converts the difference between desired vertical speed and actual speed into a desired acceleration that is passed to the throttle acceleration controller // @Range: 0.01 1.00 // @Increment: 0.01 // @User: Standard AP_SUBGROUPINFO(_p_pos, "_POS_", 9, AP_Follow, AC_P), #if !(APM_BUILD_TYPE(APM_BUILD_Rover)) // @Param: _ALT_TYPE // @DisplayName: Follow altitude type // @Description: Follow altitude type // @Values: 0:absolute, 1:relative // @User: Standard AP_GROUPINFO("_ALT_TYPE", 10, AP_Follow, _alt_type, AP_FOLLOW_ALT_TYPE_DEFAULT), #endif // @Param: _OPTIONS // @DisplayName: Follow options // @Description: Follow options bitmask // @Values: 0:None,1: Mount Follows lead vehicle on mode enter // @User: Standard AP_GROUPINFO("_OPTIONS", 11, AP_Follow, _options, 0), AP_GROUPEND }; /* The constructor also initialises the proximity sensor. Note that this constructor is not called until detect() returns true, so we already know that we should setup the proximity sensor */ AP_Follow::AP_Follow() : _p_pos(AP_FOLLOW_POS_P_DEFAULT) { _singleton = this; AP_Param::setup_object_defaults(this, var_info); } // restore offsets to zero if necessary, should be called when vehicle exits follow mode void AP_Follow::clear_offsets_if_required() { if (_offsets_were_zero) { _offset.set(Vector3f()); } _offsets_were_zero = false; } // get target's estimated location bool AP_Follow::get_target_location_and_velocity(Location &loc, Vector3f &vel_ned) const { // exit immediately if not enabled if (!_enabled) { return false; } // check for timeout if ((_last_location_update_ms == 0) || (AP_HAL::millis() - _last_location_update_ms > AP_FOLLOW_TIMEOUT_MS)) { return false; } // calculate time since last actual position update const float dt = (AP_HAL::millis() - _last_location_update_ms) * 0.001f; // get velocity estimate if (!get_velocity_ned(vel_ned, dt)) { return false; } // project the vehicle position Location last_loc = _target_location; last_loc.offset(vel_ned.x * dt, vel_ned.y * dt); last_loc.alt -= vel_ned.z * 100.0f * dt; // convert m/s to cm/s, multiply by dt. minus because NED // return latest position estimate loc = last_loc; return true; } // get distance vector to target (in meters) and target's velocity all in NED frame bool AP_Follow::get_target_dist_and_vel_ned(Vector3f &dist_ned, Vector3f &dist_with_offs, Vector3f &vel_ned) { // get our location Location current_loc; if (!AP::ahrs().get_location(current_loc)) { clear_dist_and_bearing_to_target(); return false; } // get target location and velocity Location target_loc; Vector3f veh_vel; if (!get_target_location_and_velocity(target_loc, veh_vel)) { clear_dist_and_bearing_to_target(); return false; } // change to altitude above home if relative altitude is being used if (target_loc.relative_alt == 1) { current_loc.alt -= AP::ahrs().get_home().alt; } // calculate difference const Vector3f dist_vec = current_loc.get_distance_NED(target_loc); // fail if too far if (is_positive(_dist_max.get()) && (dist_vec.length() > _dist_max)) { clear_dist_and_bearing_to_target(); return false; } // initialise offsets from distance vector if required init_offsets_if_required(dist_vec); // get offsets Vector3f offsets; if (!get_offsets_ned(offsets)) { clear_dist_and_bearing_to_target(); return false; } // calculate results dist_ned = dist_vec; dist_with_offs = dist_vec + offsets; vel_ned = veh_vel; // record distance and heading for reporting purposes if (is_zero(dist_with_offs.x) && is_zero(dist_with_offs.y)) { clear_dist_and_bearing_to_target(); } else { _dist_to_target = safe_sqrt(sq(dist_with_offs.x) + sq(dist_with_offs.y)); _bearing_to_target = degrees(atan2f(dist_with_offs.y, dist_with_offs.x)); } return true; } // get target's heading in degrees (0 = north, 90 = east) bool AP_Follow::get_target_heading_deg(float &heading) const { // exit immediately if not enabled if (!_enabled) { return false; } // check for timeout if ((_last_heading_update_ms == 0) || (AP_HAL::millis() - _last_heading_update_ms > AP_FOLLOW_TIMEOUT_MS)) { return false; } // return latest heading estimate heading = _target_heading; return true; } // handle mavlink DISTANCE_SENSOR messages void AP_Follow::handle_msg(const mavlink_message_t &msg) { // exit immediately if not enabled if (!_enabled) { return; } // skip our own messages if (msg.sysid == mavlink_system.sysid) { return; } // skip message if not from our target if (_sysid != 0 && msg.sysid != _sysid) { if (_automatic_sysid) { // maybe timeout who we were following... if ((_last_location_update_ms == 0) || (AP_HAL::millis() - _last_location_update_ms > AP_FOLLOW_SYSID_TIMEOUT_MS)) { _sysid.set(0); } } return; } // decode global-position-int message bool updated = false; switch (msg.msgid) { case MAVLINK_MSG_ID_GLOBAL_POSITION_INT: { // decode message mavlink_global_position_int_t packet; mavlink_msg_global_position_int_decode(&msg, &packet); // ignore message if lat and lon are (exactly) zero if ((packet.lat == 0 && packet.lon == 0)) { return; } _target_location.lat = packet.lat; _target_location.lng = packet.lon; // select altitude source based on FOLL_ALT_TYPE param if (_alt_type == AP_FOLLOW_ALTITUDE_TYPE_RELATIVE) { // above home alt _target_location.set_alt_cm(packet.relative_alt / 10, Location::AltFrame::ABOVE_HOME); } else { // absolute altitude _target_location.set_alt_cm(packet.alt / 10, Location::AltFrame::ABSOLUTE); } _target_velocity_ned.x = packet.vx * 0.01f; // velocity north _target_velocity_ned.y = packet.vy * 0.01f; // velocity east _target_velocity_ned.z = packet.vz * 0.01f; // velocity down // get a local timestamp with correction for transport jitter _last_location_update_ms = _jitter.correct_offboard_timestamp_msec(packet.time_boot_ms, AP_HAL::millis()); if (packet.hdg <= 36000) { // heading (UINT16_MAX if unknown) _target_heading = packet.hdg * 0.01f; // convert centi-degrees to degrees _last_heading_update_ms = _last_location_update_ms; } // initialise _sysid if zero to sender's id if (_sysid == 0) { _sysid.set(msg.sysid); _automatic_sysid = true; } updated = true; break; } case MAVLINK_MSG_ID_FOLLOW_TARGET: { // decode message mavlink_follow_target_t packet; mavlink_msg_follow_target_decode(&msg, &packet); // ignore message if lat and lon are (exactly) zero if ((packet.lat == 0 && packet.lon == 0)) { return; } // require at least position if ((packet.est_capabilities & (1<<0)) == 0) { return; } Location new_loc = _target_location; new_loc.lat = packet.lat; new_loc.lng = packet.lon; new_loc.set_alt_cm(packet.alt*100, Location::AltFrame::ABSOLUTE); // FOLLOW_TARGET is always AMSL, change the provided alt to // above home if we are configured for relative alt if (_alt_type == AP_FOLLOW_ALTITUDE_TYPE_RELATIVE && !new_loc.change_alt_frame(Location::AltFrame::ABOVE_HOME)) { return; } _target_location = new_loc; if (packet.est_capabilities & (1<<1)) { _target_velocity_ned.x = packet.vel[0]; // velocity north _target_velocity_ned.y = packet.vel[1]; // velocity east _target_velocity_ned.z = packet.vel[2]; // velocity down } else { _target_velocity_ned.zero(); } // get a local timestamp with correction for transport jitter _last_location_update_ms = _jitter.correct_offboard_timestamp_msec(packet.timestamp, AP_HAL::millis()); if (packet.est_capabilities & (1<<3)) { Quaternion q{packet.attitude_q[0], packet.attitude_q[1], packet.attitude_q[2], packet.attitude_q[3]}; float r, p, y; q.to_euler(r,p,y); _target_heading = degrees(y); _last_heading_update_ms = _last_location_update_ms; } // initialise _sysid if zero to sender's id if (_sysid == 0) { _sysid.set(msg.sysid); _automatic_sysid = true; } updated = true; break; } } if (updated) { // get estimated location and velocity Location loc_estimate{}; Vector3f vel_estimate; UNUSED_RESULT(get_target_location_and_velocity(loc_estimate, vel_estimate)); // log lead's estimated vs reported position // @LoggerMessage: FOLL // @Description: Follow library diagnostic data // @Field: TimeUS: Time since system startup // @Field: Lat: Target latitude // @Field: Lon: Target longitude // @Field: Alt: Target absolute altitude // @Field: VelN: Target earth-frame velocity, North // @Field: VelE: Target earth-frame velocity, East // @Field: VelD: Target earth-frame velocity, Down // @Field: LatE: Vehicle latitude // @Field: LonE: Vehicle longitude // @Field: AltE: Vehicle absolute altitude AP::logger().WriteStreaming("FOLL", "TimeUS,Lat,Lon,Alt,VelN,VelE,VelD,LatE,LonE,AltE", // labels "sDUmnnnDUm", // units "F--B000--B", // mults "QLLifffLLi", // fmt AP_HAL::micros64(), _target_location.lat, _target_location.lng, _target_location.alt, (double)_target_velocity_ned.x, (double)_target_velocity_ned.y, (double)_target_velocity_ned.z, loc_estimate.lat, loc_estimate.lng, loc_estimate.alt ); } } // get velocity estimate in m/s in NED frame using dt since last update bool AP_Follow::get_velocity_ned(Vector3f &vel_ned, float dt) const { vel_ned = _target_velocity_ned + (_target_accel_ned * dt); return true; } // initialise offsets to provided distance vector to other vehicle (in meters in NED frame) if required void AP_Follow::init_offsets_if_required(const Vector3f &dist_vec_ned) { // return immediately if offsets have already been set if (!_offset.get().is_zero()) { return; } _offsets_were_zero = true; float target_heading_deg; if ((_offset_type == AP_FOLLOW_OFFSET_TYPE_RELATIVE) && get_target_heading_deg(target_heading_deg)) { // rotate offsets from north facing to vehicle's perspective _offset.set(rotate_vector(-dist_vec_ned, -target_heading_deg)); gcs().send_text(MAV_SEVERITY_INFO, "Relative follow offset loaded"); } else { // initialise offset in NED frame _offset.set(-dist_vec_ned); // ensure offset_type used matches frame of offsets saved _offset_type.set(AP_FOLLOW_OFFSET_TYPE_NED); gcs().send_text(MAV_SEVERITY_INFO, "N-E-D follow offset loaded"); } } // get offsets in meters in NED frame bool AP_Follow::get_offsets_ned(Vector3f &offset) const { const Vector3f &off = _offset.get(); // if offsets are zero or type is NED, simply return offset vector if (off.is_zero() || (_offset_type == AP_FOLLOW_OFFSET_TYPE_NED)) { offset = off; return true; } // offset type is relative, exit if we cannot get vehicle's heading float target_heading_deg; if (!get_target_heading_deg(target_heading_deg)) { return false; } // rotate offsets from vehicle's perspective to NED offset = rotate_vector(off, target_heading_deg); return true; } // rotate 3D vector clockwise by specified angle (in degrees) Vector3f AP_Follow::rotate_vector(const Vector3f &vec, float angle_deg) const { // rotate roll, pitch input from north facing to vehicle's perspective const float cos_yaw = cosf(radians(angle_deg)); const float sin_yaw = sinf(radians(angle_deg)); return Vector3f((vec.x * cos_yaw) - (vec.y * sin_yaw), (vec.y * cos_yaw) + (vec.x * sin_yaw), vec.z); } // set recorded distance and bearing to target to zero void AP_Follow::clear_dist_and_bearing_to_target() { _dist_to_target = 0.0f; _bearing_to_target = 0.0f; } // get target's estimated location and velocity (in NED), with offsets added bool AP_Follow::get_target_location_and_velocity_ofs(Location &loc, Vector3f &vel_ned) const { Vector3f ofs; if (!get_offsets_ned(ofs) || !get_target_location_and_velocity(loc, vel_ned)) { return false; } // apply offsets loc.offset(ofs.x, ofs.y); loc.alt -= ofs.z*100; return true; } // return true if we have a target bool AP_Follow::have_target(void) const { if (!_enabled) { return false; } // check for timeout if ((_last_location_update_ms == 0) || (AP_HAL::millis() - _last_location_update_ms > AP_FOLLOW_TIMEOUT_MS)) { return false; } return true; } namespace AP { AP_Follow &follow() { return *AP_Follow::get_singleton(); } } #endif // AP_FOLLOW_ENABLED