// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: t -*- /// @file AP_RC_Channel.h /// @brief AP_RC_Channel manager, with EEPROM-backed storage of constants. #ifndef AP_RC_Channel_h #define AP_RC_Channel_h //#include #include /// @class AP_RC_Channel /// @brief Object managing one RC channel class AP_RC_Channel{ public: /// Constructor /// /// @param key EEPROM storage key for the channel trim parameters. /// @param name Optional name for the group. /// AP_RC_Channel(uint16_t address) : _address(address), _high(1), _filter(true), _reverse(1), dead_zone(0){} AP_RC_Channel() : _high(1), _filter(true), _reverse(1), dead_zone(0){} // setup min and max radio values in CLI void update_min_max(); void zero_min_max(); // startup void load_eeprom(void); void save_eeprom(void); void save_trim(void); void load_trim(void); void set_filter(bool filter); // setup the control preferences void set_range(int low, int high); void set_angle(int angle); void set_reverse(bool reverse); bool get_reverse(void); // read input from APM_RC - create a control_in value void set_pwm(int pwm); // pwm is stored here int16_t radio_in; // call after first set_pwm void trim(); // did our read come in 50µs below the min? bool get_failsafe(void); // value generated from PWM int16_t control_in; int16_t dead_zone; // used to keep noise down and create a dead zone. int control_mix(float value); // current values to the servos - degrees * 100 (approx assuming servo is -45 to 45 degrees except [3] is 0 to 100 int16_t servo_out; // generate PWM from servo_out value void calc_pwm(void); // PWM is without the offset from radio_min int16_t pwm_out; int16_t radio_out; int16_t radio_min; int16_t radio_trim; int16_t radio_max; // includes offset from PWM //int16_t get_radio_out(void); int16_t pwm_to_angle(); float norm_input(); float norm_output(); int16_t angle_to_pwm(); int16_t pwm_to_range(); int16_t range_to_pwm(); private: bool _filter; int8_t _reverse; int16_t _address; bool _type; int16_t _high; int16_t _low; }; #endif