#include "AP_BattMonitor_Backend.h" #include extern const AP_HAL::HAL& hal; // Write BAT data packet(s) void AP_BattMonitor_Backend::Log_Write_BAT(const uint8_t instance, const uint64_t time_us) const { bool has_curr = has_current(); const struct log_BAT pkt{ LOG_PACKET_HEADER_INIT(LOG_BAT_MSG), time_us : time_us, instance : instance, voltage : _state.voltage, voltage_resting : _state.voltage_resting_estimate, current_amps : has_curr ? _state.current_amps : AP::logger().quiet_nanf(), current_total : has_curr ? _state.consumed_mah : AP::logger().quiet_nanf(), consumed_wh : has_curr ? _state.consumed_wh : AP::logger().quiet_nanf(), temperature : (int16_t) ( has_temperature() ? _state.temperature * 100 : 0), resistance : _state.resistance, rem_percent : capacity_remaining_pct(), }; AP::logger().WriteBlock(&pkt, sizeof(pkt)); } // Write BCL data packet if has_cell_voltages void AP_BattMonitor_Backend::Log_Write_BCL(const uint8_t instance, const uint64_t time_us) const { if (!has_cell_voltages()) { return; } struct log_BCL cell_pkt{ LOG_PACKET_HEADER_INIT(LOG_BCL_MSG), time_us : time_us, instance : instance, voltage : _state.voltage }; // we pack the entire BCL message - we must have at least that // many supported cells or the loop below will over-read static_assert(ARRAY_SIZE(_state.cell_voltages.cells) >= ARRAY_SIZE(cell_pkt.cell_voltages)); for (uint8_t i = 0; i < ARRAY_SIZE(cell_pkt.cell_voltages); i++) { cell_pkt.cell_voltages[i] = _state.cell_voltages.cells[i] + 1; // add 1mv } AP::logger().WriteBlock(&cell_pkt, sizeof(cell_pkt)); #if AP_BATT_MONITOR_CELLS_MAX > 12 if (_state.cell_voltages.cells[12] != UINT16_MAX || _state.cell_voltages.cells[13] != UINT16_MAX) { // @LoggerMessage: BCL2 // @Description: Battery cell voltage information // @Field: TimeUS: Time since system startup // @Field: Instance: battery instance number // @Field: V13: thirteenth cell voltage // @Field: V14: fourteenth cell voltage AP::logger().Write( "BCL2", "TimeUS,Instance,V13,V14", "s#vv", "F-CC", "QBHH", time_us, instance, _state.cell_voltages.cells[ARRAY_SIZE(cell_pkt.cell_voltages)+0] + 1, // add 1mv _state.cell_voltages.cells[ARRAY_SIZE(cell_pkt.cell_voltages)+1] + 1 // add 1mv ); } #endif }