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Rover: add control modes class

mission-4.1.18
Peter Barker 8 years ago committed by Randy Mackay
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743d9ec65f
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2a9b1017b6
9 changed files with 683 additions and 0 deletions
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  1. 149
      APMrover2/mode.cpp
  2. 242
      APMrover2/mode.h
  3. 123
      APMrover2/mode_auto.cpp
  4. 82
      APMrover2/mode_guided.cpp
  5. 12
      APMrover2/mode_hold.cpp
  6. 2
      APMrover2/mode_learning.cpp
  7. 9
      APMrover2/mode_manual.cpp
  8. 30
      APMrover2/mode_rtl.cpp
  9. 34
      APMrover2/mode_steering.cpp

149
APMrover2/mode.cpp
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#include "mode.h"
#include "Rover.h"
Mode::Mode() :
g(rover.g),
g2(rover.g2),
channel_steer(rover.channel_steer),
channel_throttle(rover.channel_throttle),
mission(rover.mission)
{ }
void Mode::exit()
{
// call sub-classes exit
_exit();
lateral_acceleration = 0.0f;
rover.throttle = 500;
rover.g.pidSpeedThrottle.reset_I();
if (!rover.in_auto_reverse) {
rover.set_reverse(false);
}
rover.rtl_complete = false;
}
bool Mode::enter()
{
return _enter();
}
void Mode::calc_throttle(float target_speed)
{
const int16_t &throttle_nudge = rover.throttle_nudge;
int16_t &throttle = rover.throttle;
const int32_t next_navigation_leg_cd = rover.next_navigation_leg_cd;
const AP_AHRS &ahrs = rover.ahrs;
const float wp_distance = rover.wp_distance;
float &groundspeed_error = rover.groundspeed_error;
const float ground_speed = rover.ground_speed;
const float throttle_base = (fabsf(target_speed) / g.speed_cruise) * g.throttle_cruise;
const int throttle_target = throttle_base + throttle_nudge;
/*
reduce target speed in proportion to turning rate, up to the
SPEED_TURN_GAIN percentage.
*/
float steer_rate = fabsf(lateral_acceleration / (g.turn_max_g * GRAVITY_MSS));
steer_rate = constrain_float(steer_rate, 0.0f, 1.0f);
// use g.speed_turn_gain for a 90 degree turn, and in proportion
// for other turn angles
const int32_t turn_angle = wrap_180_cd(next_navigation_leg_cd - ahrs.yaw_sensor);
const float speed_turn_ratio = constrain_float(fabsf(turn_angle / 9000.0f), 0.0f, 1.0f);
const float speed_turn_reduction = (100 - g.speed_turn_gain) * speed_turn_ratio * 0.01f;
float reduction = 1.0f - steer_rate * speed_turn_reduction;
if (is_autopilot_mode() && rover.mode_guided.guided_mode != ModeGuided::Guided_Velocity && wp_distance <= g.speed_turn_dist) {
// in auto-modes we reduce speed when approaching waypoints
const float reduction2 = 1.0f - speed_turn_reduction;
if (reduction2 < reduction) {
reduction = reduction2;
}
}
// reduce the target speed by the reduction factor
target_speed *= reduction;
groundspeed_error = fabsf(target_speed) - ground_speed;
throttle = throttle_target + (g.pidSpeedThrottle.get_pid(groundspeed_error * 100.0f) / 100.0f);
// also reduce the throttle by the reduction factor. This gives a
// much faster response in turns
throttle *= reduction;
if (rover.in_reverse) {
g2.motors.set_throttle(constrain_int16(-throttle, -g.throttle_max, -g.throttle_min));
} else {
g2.motors.set_throttle(constrain_int16(throttle, g.throttle_min, g.throttle_max));
}
if (!rover.in_reverse && g.braking_percent != 0 && groundspeed_error < -g.braking_speederr) {
// the user has asked to use reverse throttle to brake. Apply
// it in proportion to the ground speed error, but only when
// our ground speed error is more than BRAKING_SPEEDERR.
//
// We use a linear gain, with 0 gain at a ground speed error
// of braking_speederr, and 100% gain when groundspeed_error
// is 2*braking_speederr
const float brake_gain = constrain_float(((-groundspeed_error)-g.braking_speederr)/g.braking_speederr, 0.0f, 1.0f);
const int16_t braking_throttle = g.throttle_max * (g.braking_percent * 0.01f) * brake_gain;
g2.motors.set_throttle(constrain_int16(-braking_throttle, -g.throttle_max, -g.throttle_min));
// temporarily set us in reverse to allow the PWM setting to
// go negative
rover.set_reverse(true);
}
if (rover.mode_guided.guided_mode != ModeGuided::Guided_Velocity) {
if (rover.use_pivot_steering()) {
// In Guided Velocity, only the steering input is used to calculate the pivot turn.
g2.motors.set_throttle(0.0f);
}
}
}
void Mode::calc_lateral_acceleration()
{
calc_lateral_acceleration(rover.current_loc, rover.next_WP);
}
/*
* Calculate desired turn angles (in medium freq loop)
*/
void Mode::calc_lateral_acceleration(const struct Location &last_WP, const struct Location &next_WP)
{
// Calculate the required turn of the wheels
// negative error = left turn
// positive error = right turn
rover.nav_controller->update_waypoint(last_WP, next_WP);
lateral_acceleration = rover.nav_controller->lateral_acceleration();
if (rover.use_pivot_steering()) {
const int16_t bearing_error = wrap_180_cd(rover.nav_controller->target_bearing_cd() - rover.ahrs.yaw_sensor) / 100;
if (bearing_error > 0) {
lateral_acceleration = g.turn_max_g * GRAVITY_MSS;
} else {
lateral_acceleration = -g.turn_max_g * GRAVITY_MSS;
}
}
}
/*
calculate steering angle given lateral_acceleration
*/
void Mode::calc_nav_steer()
{
// add in obstacle avoidance
if (!rover.in_reverse) {
lateral_acceleration += (rover.obstacle.turn_angle / 45.0f) * g.turn_max_g;
}
// constrain to max G force
lateral_acceleration = constrain_float(lateral_acceleration, -g.turn_max_g * GRAVITY_MSS, g.turn_max_g * GRAVITY_MSS);
// send final steering command to motor library
g2.motors.set_steering(rover.steerController.get_steering_out_lat_accel(lateral_acceleration));
}

242
APMrover2/mode.h
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#pragma once
#include <stdint.h>
#include <GCS_MAVLink/GCS_MAVLink.h> // for MAV_SEVERITY
#include "defines.h"
class Mode
{
public:
// Constructor
Mode();
// enter this mode, returns false if we failed to enter
bool enter();
// perform any cleanups required:
void exit();
// returns a unique number specific to this mode
virtual uint32_t mode_number() const = 0;
//
// methods that sub classes should override to affect movement of the vehicle in this mode
//
// convert user input to targets, implement high level control for this mode
virtual void update() = 0;
// calculates the amount of throttle that should be output based
// on things like proximity to corners and current speed
virtual void calc_throttle(float target_speed);
// called to determine where the vehicle should go next, and how it should get there
virtual void update_navigation() { } // most modes don't navigate
//
// attributes of the mode
//
// return if in non-manual mode : AUTO, GUIDED, RTL
virtual bool is_autopilot_mode() const { return false; }
// returns true if steering is directly controlled by RC
virtual bool manual_steering() const { return false; }
// returns true if the throttle is controlled automatically
virtual bool auto_throttle() { return is_autopilot_mode(); }
// return true if throttle should be supressed in event of a
// FAILSAFE_EVENT_THROTTLE
virtual bool failsafe_throttle_suppress() const { return true; }
//
// attributes for mavlink system status reporting
//
// returns true if any RC input is used
virtual bool has_manual_input() const { return false; }
// true if heading is controlled
virtual bool attitude_stabilized() const { return true; }
// Navigation control variables
// The instantaneous desired lateral acceleration in m/s/s
float lateral_acceleration;
protected:
// subclasses override this to perform checks before entering the mode
virtual bool _enter() { return true; }
// subclasses override this to perform any required cleanup when exiting the mode
virtual void _exit() { return; }
// calculate steering angle given a desired lateral acceleration
virtual void calc_nav_steer();
// calculate desired lateral acceleration using current location and target held in next_WP
virtual void calc_lateral_acceleration();
// calculate desired lateral acceleration
void calc_lateral_acceleration(const struct Location &last_wp, const struct Location &next_WP);
// references to avoid code churn:
class Parameters &g;
class ParametersG2 &g2;
class RC_Channel *&channel_steer; // TODO : Pointer reference ?
class RC_Channel *&channel_throttle;
class AP_Mission &mission;
};
class ModeAuto : public Mode
{
public:
uint32_t mode_number() const override { return AUTO; }
// methods that affect movement of the vehicle in this mode
void update() override;
void calc_throttle(float target_speed) override;
void update_navigation() override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
bool failsafe_throttle_suppress() const override { return false; }
protected:
bool _enter() override;
void _exit() override;
void calc_nav_steer() override;
void calc_lateral_acceleration() override;
private:
bool check_trigger(void);
// this is set to true when auto has been triggered to start
bool auto_triggered;
};
class ModeGuided : public Mode
{
public:
uint32_t mode_number() const override { return GUIDED; }
// methods that affect movement of the vehicle in this mode
void update() override;
void update_navigation() override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
bool failsafe_throttle_suppress() const override { return false; }
enum GuidedMode {
Guided_WP,
Guided_Angle,
Guided_Velocity
};
// Guided
GuidedMode guided_mode; // stores which GUIDED mode the vehicle is in
protected:
bool _enter() override;
};
class ModeHold : public Mode
{
public:
uint32_t mode_number() const override { return HOLD; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes for mavlink system status reporting
bool attitude_stabilized() const override { return false; }
};
class ModeManual : public Mode
{
public:
uint32_t mode_number() const override { return MANUAL; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes of the mode
bool manual_steering() const override { return true; }
// attributes for mavlink system status reporting
bool has_manual_input() const override { return true; }
bool attitude_stabilized() const override { return false; }
};
class ModeLearning : public ModeManual
{
public:
uint32_t mode_number() const override { return LEARNING; }
// attributes for mavlink system status reporting
bool has_manual_input() const override { return true; }
};
class ModeRTL : public Mode
{
public:
uint32_t mode_number() const override { return RTL; }
// methods that affect movement of the vehicle in this mode
void update() override;
void update_navigation() override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
bool failsafe_throttle_suppress() const override { return false; }
protected:
bool _enter() override;
};
class ModeSteering : public Mode
{
public:
uint32_t mode_number() const override { return STEERING; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes for mavlink system status reporting
bool has_manual_input() const override { return true; }
};
class ModeInitializing : public Mode
{
public:
uint32_t mode_number() const override { return INITIALISING; }
// methods that affect movement of the vehicle in this mode
void update() override { }
// attributes for mavlink system status reporting
bool has_manual_input() const override { return true; }
bool attitude_stabilized() const override { return false; }
};

123
APMrover2/mode_auto.cpp
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#include "mode.h"
#include "Rover.h"
bool ModeAuto::_enter()
{
auto_triggered = false;
rover.restart_nav();
rover.loiter_start_time = 0;
return true;
}
void ModeAuto::_exit()
{
// If we are changing out of AUTO mode reset the loiter timer
rover.loiter_start_time = 0;
// ... and stop running the mission
if (mission.state() == AP_Mission::MISSION_RUNNING) {
mission.stop();
}
}
void ModeAuto::update()
{
if (!rover.in_auto_reverse) {
rover.set_reverse(false);
}
if (!rover.do_auto_rotation) {
calc_lateral_acceleration();
calc_nav_steer();
calc_throttle(g.speed_cruise);
} else {
rover.do_yaw_rotation();
}
}
void ModeAuto::update_navigation()
{
mission.update();
if (rover.do_auto_rotation) {
rover.do_yaw_rotation();
}
}
/*
check for triggering of start of auto mode
*/
bool ModeAuto::check_trigger(void)
{
// check for user pressing the auto trigger to off
if (auto_triggered && g.auto_trigger_pin != -1 && rover.check_digital_pin(g.auto_trigger_pin) == 1) {
gcs().send_text(MAV_SEVERITY_WARNING, "AUTO triggered off");
auto_triggered = false;
return false;
}
// if already triggered, then return true, so you don't
// need to hold the switch down
if (auto_triggered) {
return true;
}
// return true if auto trigger and kickstart are disabled
if (g.auto_trigger_pin == -1 && is_zero(g.auto_kickstart)) {
// no trigger configured - let's go!
auto_triggered = true;
return true;
}
// check if trigger pin has been pushed
if (g.auto_trigger_pin != -1 && rover.check_digital_pin(g.auto_trigger_pin) == 0) {
gcs().send_text(MAV_SEVERITY_WARNING, "Triggered AUTO with pin");
auto_triggered = true;
return true;
}
// check if mission is started by giving vehicle a kick with acceleration > AUTO_KICKSTART
if (!is_zero(g.auto_kickstart)) {
const float xaccel = rover.ins.get_accel().x;
if (xaccel >= g.auto_kickstart) {
gcs().send_text(MAV_SEVERITY_WARNING, "Triggered AUTO xaccel=%.1f", static_cast<double>(xaccel));
auto_triggered = true;
return true;
}
}
return false;
}
void ModeAuto::calc_throttle(float target_speed)
{
// If not autostarting OR we are loitering at a waypoint
// then set the throttle to minimum
if (!check_trigger() || rover.in_stationary_loiter()) {
g2.motors.set_throttle(g.throttle_min.get());
// Stop rotation in case of loitering and skid steering
if (g2.motors.have_skid_steering()) {
g2.motors.set_steering(0.0f);
}
return;
}
Mode::calc_throttle(target_speed);
}
void ModeAuto::calc_lateral_acceleration()
{
// If we have reached the waypoint previously navigate
// back to it from our current position
if (rover.previously_reached_wp && (rover.loiter_duration > 0)) {
Mode::calc_lateral_acceleration(rover.current_loc, rover.next_WP);
} else {
Mode::calc_lateral_acceleration(rover.prev_WP, rover.next_WP);
}
}
void ModeAuto::calc_nav_steer()
{
// check to see if the rover is loitering
if (rover.in_stationary_loiter()) {
g2.motors.set_steering(0.0f);
return;
}
Mode::calc_nav_steer();
}

82
APMrover2/mode_guided.cpp
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#include "mode.h"
#include "Rover.h"
bool ModeGuided::_enter()
{
/*
when entering guided mode we set the target as the current
location. This matches the behaviour of the copter code.
*/
lateral_acceleration = 0.0f;
rover.set_guided_WP(rover.current_loc);
return true;
}
void ModeGuided::update()
{
if (!rover.in_auto_reverse) {
rover.set_reverse(false);
}
switch (guided_mode) {
case Guided_Angle:
rover.nav_set_yaw_speed();
break;
case Guided_WP:
if (rover.rtl_complete || rover.verify_RTL()) {
// we have reached destination so stop where we are
if (fabsf(g2.motors.get_throttle()) > g.throttle_min.get()) {
rover.gcs().send_mission_item_reached_message(0);
}
g2.motors.set_throttle(g.throttle_min.get());
g2.motors.set_steering(0.0f);
lateral_acceleration = 0.0f;
} else {
calc_lateral_acceleration();
calc_nav_steer();
calc_throttle(rover.guided_control.target_speed);
rover.Log_Write_GuidedTarget(guided_mode, Vector3f(rover.next_WP.lat, rover.next_WP.lng, rover.next_WP.alt),
Vector3f(rover.guided_control.target_speed, g2.motors.get_throttle(), 0.0f));
}
break;
case Guided_Velocity:
rover.nav_set_speed();
break;
default:
gcs().send_text(MAV_SEVERITY_WARNING, "Unknown GUIDED mode");
break;
}
}
void ModeGuided::update_navigation()
{
switch (guided_mode) {
case Guided_Angle:
rover.nav_set_yaw_speed();
break;
case Guided_WP:
// no loitering around the wp with the rover, goes direct to the wp position
if (rover.rtl_complete || rover.verify_RTL()) {
// we have reached destination so stop where we are
g2.motors.set_throttle(g.throttle_min.get());
g2.motors.set_steering(0.0f);
lateral_acceleration = 0.0f;
} else {
calc_lateral_acceleration();
calc_nav_steer();
}
break;
case Guided_Velocity:
rover.nav_set_speed();
break;
default:
gcs().send_text(MAV_SEVERITY_WARNING, "Unknown GUIDED mode");
break;
}
}

12
APMrover2/mode_hold.cpp
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#include "mode.h"
#include "Rover.h"
void ModeHold::update()
{
// hold position - stop motors and center steering
g2.motors.set_throttle(0.0f);
g2.motors.set_steering(0.0f);
if (!rover.in_auto_reverse) {
rover.set_reverse(false);
}
}

2
APMrover2/mode_learning.cpp
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#include "mode.h"
#include "Rover.h"

9
APMrover2/mode_manual.cpp
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#include "mode.h"
#include "Rover.h"
void ModeManual::update()
{
// mark us as in_reverse when using a negative throttle to
// stop AHRS getting off
rover.set_reverse(is_negative(g2.motors.get_throttle()));
}

30
APMrover2/mode_rtl.cpp
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#include "mode.h"
#include "Rover.h"
bool ModeRTL::_enter()
{
rover.do_RTL();
return true;
}
void ModeRTL::update()
{
if (!rover.in_auto_reverse) {
rover.set_reverse(false);
}
calc_lateral_acceleration();
calc_nav_steer();
calc_throttle(g.speed_cruise);
}
void ModeRTL::update_navigation()
{
// no loitering around the wp with the rover, goes direct to the wp position
if (rover.verify_RTL()) {
g2.motors.set_throttle(g.throttle_min.get());
rover.set_mode(rover.mode_hold);
} else {
calc_lateral_acceleration();
calc_nav_steer();
}
}

34
APMrover2/mode_steering.cpp
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#include "mode.h"
#include "Rover.h"
void ModeSteering::update() {
/*
in steering mode we control lateral acceleration
directly. We first calculate the maximum lateral
acceleration at full steering lock for this speed. That is
V^2/R where R is the radius of turn. We get the radius of
turn from half the STEER2SRV_P.
*/
const float ground_speed = rover.ground_speed;
float max_g_force = ground_speed * ground_speed / rover.steerController.get_turn_radius();
// constrain to user set TURN_MAX_G
max_g_force = constrain_float(max_g_force, 0.1f, g.turn_max_g * GRAVITY_MSS);
// convert pilot steering input to desired lateral acceleration
lateral_acceleration = max_g_force * (channel_steer->get_control_in() / 4500.0f);
// run steering controller
calc_nav_steer();
// convert pilot throttle input to desired speed
// speed in proportion to cruise speed, up to 50% throttle, then uses nudging above that.
float target_speed = channel_throttle->get_control_in() * 0.01f * 2.0f * g.speed_cruise;
target_speed = constrain_float(target_speed, -g.speed_cruise, g.speed_cruise);
// mark us as in_reverse when using a negative throttle to stop AHRS getting off
rover.set_reverse(is_negative(target_speed));
// run speed to throttle output controller
calc_throttle(target_speed);
}
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