ardupilot/libraries/AP_BattMonitor/AP_BattMonitor.cpp

822 lines
29 KiB
C++

#include "AP_BattMonitor.h"
#include "AP_BattMonitor_Analog.h"
#include "AP_BattMonitor_SMBus.h"
#include "AP_BattMonitor_SMBus_Solo.h"
#include "AP_BattMonitor_SMBus_Generic.h"
#include "AP_BattMonitor_SMBus_Maxell.h"
#include "AP_BattMonitor_SMBus_Rotoye.h"
#include "AP_BattMonitor_Bebop.h"
#include "AP_BattMonitor_ESC.h"
#include "AP_BattMonitor_SMBus_SUI.h"
#include "AP_BattMonitor_SMBus_NeoDesign.h"
#include "AP_BattMonitor_Sum.h"
#include "AP_BattMonitor_FuelFlow.h"
#include "AP_BattMonitor_FuelLevel_PWM.h"
#include "AP_BattMonitor_Generator.h"
#include "AP_BattMonitor_MPPT_PacketDigital.h"
#include "AP_BattMonitor_INA231.h"
#include "AP_BattMonitor_LTC2946.h"
#include "AP_BattMonitor_Torqeedo.h"
#include <AP_HAL/AP_HAL.h>
#if HAL_ENABLE_LIBUAVCAN_DRIVERS
#include "AP_BattMonitor_UAVCAN.h"
#endif
#include <AP_Vehicle/AP_Vehicle_Type.h>
#include <AP_Logger/AP_Logger.h>
#include <GCS_MAVLink/GCS.h>
#include <AP_Notify/AP_Notify.h>
extern const AP_HAL::HAL& hal;
AP_BattMonitor *AP_BattMonitor::_singleton;
const AP_Param::GroupInfo AP_BattMonitor::var_info[] = {
// 0 - 18, 20- 22 used by old parameter indexes
// Monitor 1
// @Group: _
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[0], "_", 23, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: _
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[0], "_", 41, AP_BattMonitor, backend_analog_var_info[0]),
#if AP_BATT_MONITOR_MAX_INSTANCES > 1
// @Group: 2_
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[1], "2_", 24, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: 2_
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[1], "2_", 42, AP_BattMonitor, backend_analog_var_info[1]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 2
// @Group: 3_
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[2], "3_", 25, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: 3_
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[2], "3_", 43, AP_BattMonitor, backend_analog_var_info[2]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 3
// @Group: 4_
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[3], "4_", 26, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: 4_
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[3], "4_", 44, AP_BattMonitor, backend_analog_var_info[3]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 4
// @Group: 5_
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[4], "5_", 27, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: 5_
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[4], "5_", 45, AP_BattMonitor, backend_analog_var_info[4]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 5
// @Group: 6_
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[5], "6_", 28, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: 6_
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[5], "6_", 46, AP_BattMonitor, backend_analog_var_info[5]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 6
// @Group: 7_
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[6], "7_", 29, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: 7_
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[6], "7_", 47, AP_BattMonitor, backend_analog_var_info[6]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 7
// @Group: 8_
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[7], "8_", 30, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: 8_
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[7], "8_", 48, AP_BattMonitor, backend_analog_var_info[7]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 8
// @Group: 9_
// @Path: AP_BattMonitor_Params.cpp
AP_SUBGROUPINFO(_params[8], "9_", 31, AP_BattMonitor, AP_BattMonitor_Params),
// @Group: 9_
// @Path: AP_BattMonitor_Analog.cpp
AP_SUBGROUPVARPTR(drivers[8], "9_", 49, AP_BattMonitor, backend_analog_var_info[8]),
#endif
#if HAL_BATTMON_SMBUS_ENABLE
// @Group: _
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[0], "_", 32, AP_BattMonitor, backend_smbus_var_info[0]),
#if AP_BATT_MONITOR_MAX_INSTANCES > 1
// @Group: 2_
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[1], "2_", 33, AP_BattMonitor, backend_smbus_var_info[1]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 2
// @Group: 3_
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[2], "3_", 34, AP_BattMonitor, backend_smbus_var_info[2]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 3
// @Group: 4_
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[3], "4_", 35, AP_BattMonitor, backend_smbus_var_info[3]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 4
// @Group: 5_
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[4], "5_", 36, AP_BattMonitor, backend_smbus_var_info[4]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 5
// @Group: 6_
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[5], "6_", 37, AP_BattMonitor, backend_smbus_var_info[5]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 6
// @Group: 7_
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[6], "7_", 38, AP_BattMonitor, backend_smbus_var_info[6]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 7
// @Group: 8_
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[7], "8_", 39, AP_BattMonitor, backend_smbus_var_info[7]),
#endif
#if AP_BATT_MONITOR_MAX_INSTANCES > 8
// @Group: 9_
// @Path: AP_BattMonitor_SMBus.cpp
AP_SUBGROUPVARPTR(drivers[8], "9_", 40, AP_BattMonitor, backend_smbus_var_info[8]),
#endif
#endif // HAL_BATTMON_SMBUS_ENABLE
AP_GROUPEND
};
const AP_Param::GroupInfo *AP_BattMonitor::backend_analog_var_info[AP_BATT_MONITOR_MAX_INSTANCES];
#if HAL_BATTMON_SMBUS_ENABLE
const AP_Param::GroupInfo *AP_BattMonitor::backend_smbus_var_info[AP_BATT_MONITOR_MAX_INSTANCES];
#endif
// Default constructor.
// Note that the Vector/Matrix constructors already implicitly zero
// their values.
//
AP_BattMonitor::AP_BattMonitor(uint32_t log_battery_bit, battery_failsafe_handler_fn_t battery_failsafe_handler_fn, const int8_t *failsafe_priorities) :
_log_battery_bit(log_battery_bit),
_battery_failsafe_handler_fn(battery_failsafe_handler_fn),
_failsafe_priorities(failsafe_priorities)
{
AP_Param::setup_object_defaults(this, var_info);
if (_singleton != nullptr) {
AP_HAL::panic("AP_BattMonitor must be singleton");
}
_singleton = this;
}
// init - instantiate the battery monitors
void
AP_BattMonitor::init()
{
// check init has not been called before
if (_num_instances != 0) {
return;
}
_highest_failsafe_priority = INT8_MAX;
convert_params();
#ifdef HAL_BATT_MONITOR_DEFAULT
if (_params[0]._type == 0) {
// we can't use set_default() as the type is used as a flag for parameter conversion
_params[0]._type.set(int8_t(HAL_BATT_MONITOR_DEFAULT));
}
#endif
// create each instance
for (uint8_t instance=0; instance<AP_BATT_MONITOR_MAX_INSTANCES; instance++) {
// clear out the cell voltages
memset(&state[instance].cell_voltages, 0xFF, sizeof(cells));
switch (get_type(instance)) {
case Type::ANALOG_VOLTAGE_ONLY:
case Type::ANALOG_VOLTAGE_AND_CURRENT:
drivers[instance] = new AP_BattMonitor_Analog(*this, state[instance], _params[instance]);
break;
#if HAL_BATTMON_SMBUS_ENABLE
case Type::SOLO:
drivers[instance] = new AP_BattMonitor_SMBus_Solo(*this, state[instance], _params[instance]);
break;
case Type::SMBus_Generic:
drivers[instance] = new AP_BattMonitor_SMBus_Generic(*this, state[instance], _params[instance]);
break;
case Type::SUI3:
drivers[instance] = new AP_BattMonitor_SMBus_SUI(*this, state[instance], _params[instance], 3);
break;
case Type::SUI6:
drivers[instance] = new AP_BattMonitor_SMBus_SUI(*this, state[instance], _params[instance], 6);
break;
case Type::MAXELL:
drivers[instance] = new AP_BattMonitor_SMBus_Maxell(*this, state[instance], _params[instance]);
break;
case Type::Rotoye:
drivers[instance] = new AP_BattMonitor_SMBus_Rotoye(*this, state[instance], _params[instance]);
break;
case Type::NeoDesign:
drivers[instance] = new AP_BattMonitor_SMBus_NeoDesign(*this, state[instance], _params[instance]);
break;
#endif // HAL_BATTMON_SMBUS_ENABLE
case Type::BEBOP:
#if CONFIG_HAL_BOARD_SUBTYPE == HAL_BOARD_SUBTYPE_LINUX_BEBOP || CONFIG_HAL_BOARD_SUBTYPE == HAL_BOARD_SUBTYPE_LINUX_DISCO
drivers[instance] = new AP_BattMonitor_Bebop(*this, state[instance], _params[instance]);
#endif
break;
case Type::UAVCAN_BatteryInfo:
#if HAL_ENABLE_LIBUAVCAN_DRIVERS
drivers[instance] = new AP_BattMonitor_UAVCAN(*this, state[instance], AP_BattMonitor_UAVCAN::UAVCAN_BATTERY_INFO, _params[instance]);
#endif
break;
case Type::BLHeliESC:
#if HAL_WITH_ESC_TELEM && !defined(HAL_BUILD_AP_PERIPH)
drivers[instance] = new AP_BattMonitor_ESC(*this, state[instance], _params[instance]);
#endif
break;
case Type::Sum:
drivers[instance] = new AP_BattMonitor_Sum(*this, state[instance], _params[instance], instance);
break;
#if HAL_BATTMON_FUEL_ENABLE
case Type::FuelFlow:
drivers[instance] = new AP_BattMonitor_FuelFlow(*this, state[instance], _params[instance]);
break;
case Type::FuelLevel_PWM:
drivers[instance] = new AP_BattMonitor_FuelLevel_PWM(*this, state[instance], _params[instance]);
break;
#endif // HAL_BATTMON_FUEL_ENABLE
#if HAL_GENERATOR_ENABLED
case Type::GENERATOR_ELEC:
drivers[instance] = new AP_BattMonitor_Generator_Elec(*this, state[instance], _params[instance]);
break;
case Type::GENERATOR_FUEL:
drivers[instance] = new AP_BattMonitor_Generator_FuelLevel(*this, state[instance], _params[instance]);
break;
#endif // HAL_GENERATOR_ENABLED
#if HAL_MPPT_PACKETDIGITAL_CAN_ENABLE
case Type::MPPT_PacketDigital:
drivers[instance] = new AP_BattMonitor_MPPT_PacketDigital(*this, state[instance], _params[instance]);
break;
#endif // HAL_MPPT_PACKETDIGITAL_CAN_ENABLE
#if HAL_BATTMON_INA231_ENABLED
case Type::INA231:
drivers[instance] = new AP_BattMonitor_INA231(*this, state[instance], _params[instance]);
break;
#endif
#if HAL_BATTMON_LTC2946_ENABLED
case Type::LTC2946:
drivers[instance] = new AP_BattMonitor_LTC2946(*this, state[instance], _params[instance]);
break;
#endif
#if HAL_TORQEEDO_ENABLED
case Type::Torqeedo:
drivers[instance] = new AP_BattMonitor_Torqeedo(*this, state[instance], _params[instance]);
break;
#endif
case Type::NONE:
default:
break;
}
// if the backend has some local parameters then make those available in the tree
if (drivers[instance] && state[instance].var_info) {
Type type = get_type(instance);
if((type == Type::ANALOG_VOLTAGE_AND_CURRENT) || (type == Type::ANALOG_VOLTAGE_ONLY) ||
(type == Type::FuelFlow) || (type == Type::FuelLevel_PWM)) {
backend_analog_var_info[instance] = state[instance].var_info;
AP_Param::load_object_from_eeprom(drivers[instance], backend_analog_var_info[instance]);
}
#if HAL_BATTMON_SMBUS_ENABLE
else if ((type == Type::MAXELL) || (type == Type::NeoDesign) || (type == Type::Rotoye) || (type == Type::SMBus_Generic) ||
(type == Type::SOLO) || (type == Type::SUI3) || (type == Type::SUI6)) {
backend_smbus_var_info[instance] = state[instance].var_info;
AP_Param::load_object_from_eeprom(drivers[instance], backend_smbus_var_info[instance]);
}
#endif
// param count could have changed
AP_Param::invalidate_count();
}
// call init function for each backend
if (drivers[instance] != nullptr) {
drivers[instance]->init();
// _num_instances is actually the index for looping over instances
// the user may have BATT_MONITOR=0 and BATT2_MONITOR=7, in which case
// there will be a gap, but as we always check for drivers[instances] being nullptr
// this is safe
_num_instances = instance + 1;
// Convert the old analog & Bus parameters to the new dynamic parameter groups
convert_dynamic_param_groups(instance);
}
}
}
void AP_BattMonitor::convert_dynamic_param_groups(uint8_t instance)
{
AP_Param::ConversionInfo info;
if (!AP_Param::find_top_level_key_by_pointer(this, info.old_key)) {
return;
}
char param_prefix[6] {};
char param_name[17] {};
info.new_name = param_name;
const uint8_t param_instance = instance + 1;
// first battmonitor does not have '1' in the param name
if(param_instance == 1) {
hal.util->snprintf(param_prefix, sizeof(param_prefix), "BATT");
} else {
hal.util->snprintf(param_prefix, sizeof(param_prefix), "BATT%X", param_instance);
}
param_prefix[sizeof(param_prefix)-1] = '\0';
hal.util->snprintf(param_name, sizeof(param_name), "%s_%s", param_prefix, "MONITOR");
param_name[sizeof(param_name)-1] = '\0';
// Find the index of the BATTn_MONITOR which is not moving to index the moving parameters off from
AP_Param::ParamToken token = AP_Param::ParamToken {};
ap_var_type type;
AP_Param* param = AP_Param::find_by_name(param_name, &type, &token);
const uint8_t battmonitor_index = 1;
if( param == nullptr) {
// BATTn_MONITOR not found
return;
}
const struct convert_table {
uint32_t old_group_element;
ap_var_type type;
const char* new_name;
} conversion_table[] = {
{ 2, AP_PARAM_INT8, "VOLT_PIN" },
{ 3, AP_PARAM_INT8, "CURR_PIN" },
{ 4, AP_PARAM_FLOAT, "VOLT_MULT" },
{ 5, AP_PARAM_FLOAT, "AMP_PERVLT"},
{ 6, AP_PARAM_FLOAT, "AMP_OFFSET"},
{ 20, AP_PARAM_INT8, "I2C_BUS" },
};
for (const auto & elem : conversion_table) {
info.old_group_element = token.group_element + ((elem.old_group_element - battmonitor_index) * 64);;
info.type = elem.type;
hal.util->snprintf(param_name, sizeof(param_name), "%s_%s", param_prefix, elem.new_name);
AP_Param::convert_old_parameter(&info, 1.0f, 0);
}
}
void AP_BattMonitor::convert_params(void) {
if (_params[0]._type.configured_in_storage()) {
// _params[0]._type will always be configured in storage after conversion is done the first time
return;
}
#define SECOND_BATT_CONVERT_MASK 0x80
const struct ConversionTable {
uint8_t old_element;
uint8_t new_index; // upper bit used to indicate if its the first or second instance
}conversionTable[22] = {
{ 0, 0 }, // _MONITOR
{ 1, 1 }, // _VOLT_PIN
{ 2, 2 }, // _CURR_PIN
{ 3, 3 }, // _VOLT_MULT
{ 4, 4 }, // _AMP_PERVOLT
{ 5, 5 }, // _AMP_OFFSET
{ 6, 6 }, // _CAPACITY
{ 9, 7 }, // _WATT_MAX
{10, 8 }, // _SERIAL_NUM
{11, (SECOND_BATT_CONVERT_MASK | 0)}, // 2_MONITOR
{12, (SECOND_BATT_CONVERT_MASK | 1)}, // 2_VOLT_PIN
{13, (SECOND_BATT_CONVERT_MASK | 2)}, // 2_CURR_PIN
{14, (SECOND_BATT_CONVERT_MASK | 3)}, // 2_VOLT_MULT
{15, (SECOND_BATT_CONVERT_MASK | 4)}, // 2_AMP_PERVOLT
{16, (SECOND_BATT_CONVERT_MASK | 5)}, // 2_AMP_OFFSET
{17, (SECOND_BATT_CONVERT_MASK | 6)}, // 2_CAPACITY
{18, (SECOND_BATT_CONVERT_MASK | 7)}, // 2_WATT_MAX
{20, (SECOND_BATT_CONVERT_MASK | 8)}, // 2_SERIAL_NUM
{21, 9 }, // _LOW_TIMER
{22, 10 }, // _LOW_TYPE
{21, (SECOND_BATT_CONVERT_MASK | 9)}, // 2_LOW_TIMER
{22, (SECOND_BATT_CONVERT_MASK |10)}, // 2_LOW_TYPE
};
char param_name[17];
AP_Param::ConversionInfo info;
info.new_name = param_name;
#if APM_BUILD_TYPE(APM_BUILD_ArduPlane)
info.old_key = 166;
#elif APM_BUILD_COPTER_OR_HELI
info.old_key = 36;
#elif APM_BUILD_TYPE(APM_BUILD_ArduSub)
info.old_key = 33;
#elif APM_BUILD_TYPE(APM_BUILD_Rover)
info.old_key = 145;
#else
_params[0]._type.save(true);
return; // no conversion is supported on this platform
#endif
for (uint8_t i = 0; i < ARRAY_SIZE(conversionTable); i++) {
uint8_t param_instance = conversionTable[i].new_index >> 7;
uint8_t destination_index = 0x7F & conversionTable[i].new_index;
info.old_group_element = conversionTable[i].old_element;
info.type = (ap_var_type)AP_BattMonitor_Params::var_info[destination_index].type;
if (param_instance) {
hal.util->snprintf(param_name, sizeof(param_name), "BATT2_%s", AP_BattMonitor_Params::var_info[destination_index].name);
} else {
hal.util->snprintf(param_name, sizeof(param_name), "BATT_%s", AP_BattMonitor_Params::var_info[destination_index].name);
}
AP_Param::convert_old_parameter(&info, 1.0f, 0);
}
// force _params[0]._type into storage to flag that conversion has been done
_params[0]._type.save(true);
}
// read - For all active instances read voltage & current; log BAT, BCL, POWR
void AP_BattMonitor::read()
{
#ifndef HAL_BUILD_AP_PERIPH
AP_Logger *logger = AP_Logger::get_singleton();
if (logger != nullptr && logger->should_log(_log_battery_bit)) {
logger->Write_Power();
}
#endif
for (uint8_t i=0; i<_num_instances; i++) {
if (drivers[i] != nullptr && get_type(i) != Type::NONE) {
drivers[i]->read();
drivers[i]->update_resistance_estimate();
#ifndef HAL_BUILD_AP_PERIPH
if (logger != nullptr && logger->should_log(_log_battery_bit)) {
const uint64_t time_us = AP_HAL::micros64();
drivers[i]->Log_Write_BAT(i, time_us);
drivers[i]->Log_Write_BCL(i, time_us);
}
#endif
}
}
check_failsafes();
checkPoweringOff();
}
// healthy - returns true if monitor is functioning
bool AP_BattMonitor::healthy(uint8_t instance) const {
return instance < _num_instances && state[instance].healthy;
}
/// voltage - returns battery voltage in volts
float AP_BattMonitor::voltage(uint8_t instance) const
{
if (instance < _num_instances) {
return state[instance].voltage;
} else {
return 0.0f;
}
}
/// get voltage with sag removed (based on battery current draw and resistance)
/// this will always be greater than or equal to the raw voltage
float AP_BattMonitor::voltage_resting_estimate(uint8_t instance) const
{
if (instance < _num_instances && drivers[instance] != nullptr) {
return drivers[instance]->voltage_resting_estimate();
} else {
return 0.0f;
}
}
/// current_amps - returns the instantaneous current draw in amperes
bool AP_BattMonitor::current_amps(float &current, uint8_t instance) const {
if ((instance < _num_instances) && (drivers[instance] != nullptr) && drivers[instance]->has_current()) {
current = state[instance].current_amps;
return true;
} else {
return false;
}
}
/// consumed_mah - returns total current drawn since start-up in milliampere.hours
bool AP_BattMonitor::consumed_mah(float &mah, const uint8_t instance) const {
if ((instance < _num_instances) && (drivers[instance] != nullptr) && drivers[instance]->has_current()) {
mah = state[instance].consumed_mah;
return true;
} else {
return false;
}
}
/// consumed_wh - returns energy consumed since start-up in Watt.hours
bool AP_BattMonitor::consumed_wh(float &wh, const uint8_t instance) const {
if (instance < _num_instances && drivers[instance] != nullptr && drivers[instance]->has_consumed_energy()) {
wh = state[instance].consumed_wh;
return true;
} else {
return false;
}
}
/// capacity_remaining_pct - returns true if the percentage is valid and writes to percentage argument
bool AP_BattMonitor::capacity_remaining_pct(uint8_t &percentage, uint8_t instance) const
{
if (instance < _num_instances && drivers[instance] != nullptr) {
return drivers[instance]->capacity_remaining_pct(percentage);
}
return false;
}
/// time_remaining - returns remaining battery time
bool AP_BattMonitor::time_remaining(uint32_t &seconds, uint8_t instance) const
{
if (instance < _num_instances && drivers[instance] != nullptr && state[instance].has_time_remaining) {
seconds = state[instance].time_remaining;
return true;
}
return false;
}
/// pack_capacity_mah - returns the capacity of the battery pack in mAh when the pack is full
int32_t AP_BattMonitor::pack_capacity_mah(uint8_t instance) const
{
if (instance < AP_BATT_MONITOR_MAX_INSTANCES) {
return _params[instance]._pack_capacity;
} else {
return 0;
}
}
void AP_BattMonitor::check_failsafes(void)
{
if (hal.util->get_soft_armed()) {
for (uint8_t i = 0; i < _num_instances; i++) {
if (drivers[i] == nullptr) {
continue;
}
const Failsafe type = drivers[i]->update_failsafes();
if (type <= state[i].failsafe) {
continue;
}
int8_t action = 0;
const char *type_str = nullptr;
switch (type) {
case Failsafe::None:
continue; // should not have been called in this case
case Failsafe::Low:
action = _params[i]._failsafe_low_action;
type_str = "low";
break;
case Failsafe::Critical:
action = _params[i]._failsafe_critical_action;
type_str = "critical";
break;
}
GCS_SEND_TEXT(MAV_SEVERITY_WARNING, "Battery %d is %s %.2fV used %.0f mAh", i + 1, type_str,
(double)voltage(i), (double)state[i].consumed_mah);
_has_triggered_failsafe = true;
#ifndef HAL_BUILD_AP_PERIPH
AP_Notify::flags.failsafe_battery = true;
#endif
state[i].failsafe = type;
// map the desired failsafe action to a prioritiy level
int8_t priority = 0;
if (_failsafe_priorities != nullptr) {
while (_failsafe_priorities[priority] != -1) {
if (_failsafe_priorities[priority] == action) {
break;
}
priority++;
}
}
// trigger failsafe if the action was equal or higher priority
// It's valid to retrigger the same action if a different battery provoked the event
if (priority <= _highest_failsafe_priority) {
_battery_failsafe_handler_fn(type_str, action);
_highest_failsafe_priority = priority;
}
}
}
}
// return true if any battery is pushing too much power
bool AP_BattMonitor::overpower_detected() const
{
bool result = false;
for (uint8_t instance = 0; instance < _num_instances; instance++) {
result |= overpower_detected(instance);
}
return result;
}
bool AP_BattMonitor::overpower_detected(uint8_t instance) const
{
#if APM_BUILD_TYPE(APM_BUILD_ArduPlane)
if (instance < _num_instances && _params[instance]._watt_max > 0) {
float power = state[instance].current_amps * state[instance].voltage;
return state[instance].healthy && (power > _params[instance]._watt_max);
}
return false;
#else
return false;
#endif
}
bool AP_BattMonitor::has_cell_voltages(const uint8_t instance) const
{
if (instance < _num_instances && drivers[instance] != nullptr) {
return drivers[instance]->has_cell_voltages();
}
return false;
}
// return the current cell voltages, returns the first monitor instances cells if the instance is out of range
const AP_BattMonitor::cells & AP_BattMonitor::get_cell_voltages(const uint8_t instance) const
{
if (instance >= AP_BATT_MONITOR_MAX_INSTANCES) {
return state[AP_BATT_PRIMARY_INSTANCE].cell_voltages;
} else {
return state[instance].cell_voltages;
}
}
// returns true if there is a temperature reading
bool AP_BattMonitor::get_temperature(float &temperature, const uint8_t instance) const
{
if (instance >= AP_BATT_MONITOR_MAX_INSTANCES || drivers[instance] == nullptr) {
return false;
}
temperature = state[instance].temperature;
return drivers[instance]->has_temperature();
}
// return true if cycle count can be provided and fills in cycles argument
bool AP_BattMonitor::get_cycle_count(uint8_t instance, uint16_t &cycles) const
{
if (instance >= AP_BATT_MONITOR_MAX_INSTANCES || (drivers[instance] == nullptr)) {
return false;
}
return drivers[instance]->get_cycle_count(cycles);
}
bool AP_BattMonitor::arming_checks(size_t buflen, char *buffer) const
{
char temp_buffer[MAVLINK_MSG_STATUSTEXT_FIELD_TEXT_LEN+1] {};
for (uint8_t i = 0; i < AP_BATT_MONITOR_MAX_INSTANCES; i++) {
if (drivers[i] != nullptr && !(drivers[i]->arming_checks(temp_buffer, sizeof(temp_buffer)))) {
hal.util->snprintf(buffer, buflen, "Battery %d %s", i + 1, temp_buffer);
return false;
}
}
return true;
}
// Check's each smart battery instance for its powering off state and broadcasts notifications
void AP_BattMonitor::checkPoweringOff(void)
{
for (uint8_t i = 0; i < _num_instances; i++) {
if (state[i].is_powering_off && !state[i].powerOffNotified) {
#ifndef HAL_BUILD_AP_PERIPH
// Set the AP_Notify flag, which plays the power off tones
AP_Notify::flags.powering_off = true;
#endif
// Send a Mavlink broadcast announcing the shutdown
#if HAL_GCS_ENABLED
mavlink_command_long_t cmd_msg{};
cmd_msg.command = MAV_CMD_POWER_OFF_INITIATED;
cmd_msg.param1 = i+1;
GCS_MAVLINK::send_to_components(MAVLINK_MSG_ID_COMMAND_LONG, (char*)&cmd_msg, sizeof(cmd_msg));
gcs().send_text(MAV_SEVERITY_WARNING, "Vehicle %d battery %d is powering off", mavlink_system.sysid, i+1);
#endif
// only send this once
state[i].powerOffNotified = true;
}
}
}
/*
reset battery remaining percentage for batteries that integrate to
calculate percentage remaining
*/
bool AP_BattMonitor::reset_remaining_mask(uint16_t battery_mask, float percentage)
{
static_assert(AP_BATT_MONITOR_MAX_INSTANCES <= 16, "More batteries are enabled then can be reset");
bool ret = true;
Failsafe highest_failsafe = Failsafe::None;
for (uint8_t i = 0; i < _num_instances; i++) {
if ((1U<<i) & battery_mask) {
if (drivers[i] != nullptr) {
ret &= drivers[i]->reset_remaining(percentage);
} else {
ret = false;
}
}
if (state[i].failsafe > highest_failsafe) {
highest_failsafe = state[i].failsafe;
}
}
// If all backends are not in failsafe then set overall failsafe state
if (highest_failsafe == Failsafe::None) {
_highest_failsafe_priority = INT8_MAX;
_has_triggered_failsafe = false;
// and reset notify flag
AP_Notify::flags.failsafe_battery = false;
}
return ret;
}
// Returns the mavlink charge state. The following mavlink charge states are not used
// MAV_BATTERY_CHARGE_STATE_EMERGENCY , MAV_BATTERY_CHARGE_STATE_FAILED
// MAV_BATTERY_CHARGE_STATE_UNHEALTHY, MAV_BATTERY_CHARGE_STATE_CHARGING
MAV_BATTERY_CHARGE_STATE AP_BattMonitor::get_mavlink_charge_state(const uint8_t instance) const
{
if (instance >= _num_instances) {
return MAV_BATTERY_CHARGE_STATE_UNDEFINED;
}
switch (state[instance].failsafe) {
case Failsafe::None:
return MAV_BATTERY_CHARGE_STATE_OK;
case Failsafe::Low:
return MAV_BATTERY_CHARGE_STATE_LOW;
case Failsafe::Critical:
return MAV_BATTERY_CHARGE_STATE_CRITICAL;
}
// Should not reach this
return MAV_BATTERY_CHARGE_STATE_UNDEFINED;
}
namespace AP {
AP_BattMonitor &battery()
{
return *AP_BattMonitor::get_singleton();
}
};