/* 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 . */ /* Rover Sailboat functionality */ class Sailboat { public: // constructor Sailboat(); // enabled bool sail_enabled() const { return enable > 0;} // true if sailboat navigation (aka tacking) is enabled bool tack_enabled() const; // setup void init(); // initialise rc input (channel_mainsail) void init_rc_in(); // decode pilot mainsail input and return in steer_out and throttle_out arguments // mainsail_out is in the range 0 to 100, defaults to 100 (fully relaxed) if no input configured // wingsail_out is in the range -100 to 100, defaults to 0 void get_pilot_desired_mainsail(float &mainsail_out, float &wingsail_out); // calculate throttle and mainsail angle required to attain desired speed (in m/s) void get_throttle_and_mainsail_out(float desired_speed, float &throttle_out, float &mainsail_out, float &wingsail_out); // Velocity Made Good, this is the speed we are traveling towards the desired destination float get_VMG() const; // handle user initiated tack while in acro mode void handle_tack_request_acro(); // return target heading in radians when tacking (only used in acro) float get_tack_heading_rad(); // handle user initiated tack while in autonomous modes (Auto, Guided, RTL, SmartRTL, etc) void handle_tack_request_auto(); // clear tacking state variables void clear_tack(); // returns true if boat is currently tacking bool tacking() const; // returns true if sailboat should take a indirect navigation route to go upwind bool use_indirect_route(float desired_heading_cd) const; // calculate the heading to sail on if we cant go upwind float calc_heading(float desired_heading_cd); // states of USE_MOTOR parameter and motor_state variable enum class UseMotor { USE_MOTOR_NEVER = 0, USE_MOTOR_ASSIST = 1, USE_MOTOR_ALWAYS = 2 }; // set state of motor // if report_failure is true a message will be sent to all GCSs void set_motor_state(UseMotor state, bool report_failure = true); // var_info for holding Parameter information static const struct AP_Param::GroupInfo var_info[]; // return sailboat loiter radius float get_loiter_radius() const {return loit_radius;} private: // true if motor is on to assist with slow tack bool motor_assist_tack() const; // true if motor should be on to assist with low wind bool motor_assist_low_wind() const; // parameters AP_Int8 enable; AP_Float sail_angle_min; AP_Float sail_angle_max; AP_Float sail_angle_ideal; AP_Float sail_heel_angle_max; AP_Float sail_no_go; AP_Float sail_windspeed_min; AP_Float xtrack_max; AP_Float loit_radius; RC_Channel *channel_mainsail; // rc input channel for controlling mainsail bool currently_tacking; // true when sailboat is in the process of tacking to a new heading float tack_heading_rad; // target heading in radians while tacking in either acro or autonomous modes uint32_t tack_request_ms; // system time user requested tack uint32_t auto_tack_start_ms; // system time when tack was started in autonomous mode uint32_t tack_clear_ms; // system time when tack was cleared bool tack_assist; // true if we should use some throttle to assist tack UseMotor motor_state; // current state of motor output };