#pragma once #include "AP_BattMonitor.h" #include "AP_BattMonitor_Backend.h" #include #include #define AP_BATTMONITOR_UAVCAN_TIMEOUT_MICROS 5000000 // sensor becomes unhealthy if no successful readings for 5 seconds #ifndef AP_BATTMONITOR_UAVCAN_MPPT_DEBUG #define AP_BATTMONITOR_UAVCAN_MPPT_DEBUG 0 #endif class BattInfoCb; class BattInfoAuxCb; class MpptStreamCb; class AP_BattMonitor_UAVCAN : public AP_BattMonitor_Backend { public: enum BattMonitor_UAVCAN_Type { UAVCAN_BATTERY_INFO = 0 }; /// Constructor AP_BattMonitor_UAVCAN(AP_BattMonitor &mon, AP_BattMonitor::BattMonitor_State &mon_state, BattMonitor_UAVCAN_Type type, AP_BattMonitor_Params ¶ms); static const struct AP_Param::GroupInfo var_info[]; void init() override {} /// Read the battery voltage and current. Should be called at 10hz void read() override; /// capacity_remaining_pct - returns true if the percentage is valid and writes to percentage argument bool capacity_remaining_pct(uint8_t &percentage) const override; bool has_temperature() const override { return _has_temperature; } bool has_current() const override { return true; } bool has_consumed_energy() const override { return _has_consumed_energy; } bool has_time_remaining() const override { return _has_time_remaining; } bool has_cell_voltages() const override { return _has_cell_voltages; } bool get_cycle_count(uint16_t &cycles) const override; // return mavlink fault bitmask (see MAV_BATTERY_FAULT enum) uint32_t get_mavlink_fault_bitmask() const override; static void subscribe_msgs(AP_UAVCAN* ap_uavcan); static AP_BattMonitor_UAVCAN* get_uavcan_backend(AP_UAVCAN* ap_uavcan, uint8_t node_id, uint8_t battery_id); static void handle_battery_info_trampoline(AP_UAVCAN* ap_uavcan, uint8_t node_id, const BattInfoCb &cb); static void handle_battery_info_aux_trampoline(AP_UAVCAN* ap_uavcan, uint8_t node_id, const BattInfoAuxCb &cb); static void handle_mppt_stream_trampoline(AP_UAVCAN* ap_uavcan, uint8_t node_id, const MpptStreamCb &cb); void handle_outputEnable_response(const uint8_t nodeId, const bool enabled); void mppt_set_powered_state(bool power_on) override; private: void handle_battery_info(const BattInfoCb &cb); void handle_battery_info_aux(const BattInfoAuxCb &cb); void update_interim_state(const float voltage, const float current, const float temperature_K, const uint8_t soc); static bool match_battery_id(uint8_t instance, uint8_t battery_id) { // when serial number is negative, all batteries are accepted. Else, it must match return (AP::battery().get_serial_number(instance) < 0) || (AP::battery().get_serial_number(instance) == (int32_t)battery_id); } // MPPT related enums and methods enum class MPPT_FaultFlags : uint8_t { OVER_VOLTAGE = (1U<<0), UNDER_VOLTAGE = (1U<<1), OVER_CURRENT = (1U<<2), OVER_TEMPERATURE = (1U<<3), }; void handle_mppt_stream(const MpptStreamCb &cb); void mppt_check_powered_state(); #if AP_BATTMONITOR_UAVCAN_MPPT_DEBUG static void mppt_report_faults(const uint8_t instance, const uint8_t fault_flags); static const char* mppt_fault_string(const MPPT_FaultFlags fault); #endif AP_BattMonitor::BattMonitor_State _interim_state; BattMonitor_UAVCAN_Type _type; HAL_Semaphore _sem_battmon; AP_UAVCAN* _ap_uavcan; uint8_t _soc; uint8_t _node_id; uint16_t _cycle_count; float _remaining_capacity_wh; float _full_charge_capacity_wh; bool _has_temperature; bool _has_cell_voltages; bool _has_time_remaining; bool _has_consumed_energy; bool _has_battery_info_aux; uint8_t _instance; // instance of this battery monitor uavcan::Node<0> *_node; // UAVCAN node id AP_Float _curr_mult; // scaling multiplier applied to current reports for adjustment // MPPT variables struct { bool is_detected; // true if this UAVCAN device is a Packet Digital MPPT bool powered_state; // true if the mppt is powered on, false if powered off bool vehicle_armed_last; // latest vehicle armed state. used to detect changes and power on/off MPPT board uint8_t fault_flags; // bits holding fault flags uint32_t powered_state_remote_ms; // timestamp of when request was sent, zeroed on response. Used to retry } _mppt; };