/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- #ifndef AP_BATTMONITOR_H #define AP_BATTMONITOR_H #include #include #include // maximum number of battery monitors #define AP_BATT_MONITOR_MAX_INSTANCES 2 // first monitor is always the primary monitor #define AP_BATT_PRIMARY_INSTANCE 0 #define AP_BATT_CAPACITY_DEFAULT 3300 #define AP_BATT_LOW_VOLT_TIMEOUT_MS 10000 // low voltage of 10 seconds will cause battery_exhausted to return true // declare backend class class AP_BattMonitor_Backend; class AP_BattMonitor_Analog; class AP_BattMonitor_SMBus; class AP_BattMonitor_SMBus_I2C; class AP_BattMonitor_SMBus_PX4; class AP_BattMonitor { friend class AP_BattMonitor_Backend; friend class AP_BattMonitor_Analog; friend class AP_BattMonitor_SMBus; friend class AP_BattMonitor_SMBus_I2C; friend class AP_BattMonitor_SMBus_PX4; public: /// Constructor AP_BattMonitor(); // Battery monitor driver types enum BattMonitor_Type { BattMonitor_TYPE_NONE = 0, BattMonitor_TYPE_ANALOG_VOLTAGE_ONLY = 3, BattMonitor_TYPE_ANALOG_VOLTAGE_AND_CURRENT = 4, BattMonitor_TYPE_SMBUS = 5 }; // The BattMonitor_State structure is filled in by the backend driver struct BattMonitor_State { uint8_t instance; // the instance number of this monitor bool healthy; // battery monitor is communicating correctly float voltage; // voltage in volts float current_amps; // current in amperes float current_total_mah; // total current draw since start-up uint32_t last_time_micros; // time when voltage and current was last read uint32_t low_voltage_start_ms; // time when voltage dropped below the minimum }; // Return the number of battery monitor instances uint8_t num_instances(void) const { return _num_instances; } // detect and initialise any available battery monitors void init(); /// Read the battery voltage and current for all batteries. Should be called at 10hz void read(); #define _BattMonitor_STATE(instance) state[instance] // healthy - returns true if monitor is functioning bool healthy(uint8_t instance) const; bool healthy() const { return healthy(AP_BATT_PRIMARY_INSTANCE); } /// has_current - returns true if battery monitor instance provides current info bool has_current(uint8_t instance) const; bool has_current() const { return has_current(AP_BATT_PRIMARY_INSTANCE); } /// voltage - returns battery voltage in millivolts float voltage(uint8_t instance) const; float voltage() const { return voltage(AP_BATT_PRIMARY_INSTANCE); } // voltage2 - returns the voltage of the second battery (helper function to send 2nd voltage to GCS) float voltage2() const; /// current_amps - returns the instantaneous current draw in amperes float current_amps(uint8_t instance) const; float current_amps() const { return current_amps(AP_BATT_PRIMARY_INSTANCE); } /// current_total_mah - returns total current drawn since start-up in amp-hours float current_total_mah(uint8_t instance) const; float current_total_mah() const { return current_total_mah(AP_BATT_PRIMARY_INSTANCE); } /// capacity_remaining_pct - returns the % battery capacity remaining (0 ~ 100) virtual uint8_t capacity_remaining_pct(uint8_t instance) const; uint8_t capacity_remaining_pct() const { return capacity_remaining_pct(AP_BATT_PRIMARY_INSTANCE); } /// exhausted - returns true if the battery's voltage remains below the low_voltage for 10 seconds or remaining capacity falls below min_capacity bool exhausted(uint8_t instance, float low_voltage, float min_capacity_mah); bool exhausted(float low_voltage, float min_capacity_mah) { return exhausted(AP_BATT_PRIMARY_INSTANCE, low_voltage, min_capacity_mah); } /// get_type - returns battery monitor type enum BattMonitor_Type get_type() { return get_type(AP_BATT_PRIMARY_INSTANCE); } enum BattMonitor_Type get_type(uint8_t instance) { return (enum BattMonitor_Type)_monitoring[instance].get(); } /// set_monitoring - sets the monitor type (used for example sketch only) void set_monitoring(uint8_t instance, uint8_t mon) { _monitoring[instance].set(mon); } static const struct AP_Param::GroupInfo var_info[]; protected: /// parameters AP_Int8 _monitoring[AP_BATT_MONITOR_MAX_INSTANCES]; /// 0=disabled, 3=voltage only, 4=voltage and current AP_Int8 _volt_pin[AP_BATT_MONITOR_MAX_INSTANCES]; /// board pin used to measure battery voltage AP_Int8 _curr_pin[AP_BATT_MONITOR_MAX_INSTANCES]; /// board pin used to measure battery current AP_Float _volt_multiplier[AP_BATT_MONITOR_MAX_INSTANCES]; /// voltage on volt pin multiplied by this to calculate battery voltage AP_Float _curr_amp_per_volt[AP_BATT_MONITOR_MAX_INSTANCES]; /// voltage on current pin multiplied by this to calculate current in amps AP_Float _curr_amp_offset[AP_BATT_MONITOR_MAX_INSTANCES]; /// offset voltage that is subtracted from current pin before conversion to amps AP_Int32 _pack_capacity[AP_BATT_MONITOR_MAX_INSTANCES]; /// battery pack capacity less reserve in mAh private: BattMonitor_State state[AP_BATT_MONITOR_MAX_INSTANCES]; AP_BattMonitor_Backend *drivers[AP_BATT_MONITOR_MAX_INSTANCES]; uint8_t _num_instances; /// number of monitors }; #endif // AP_BATTMONITOR_H