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/**
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* @ addtogroup OpenPilotModules OpenPilot Modules
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* @ {
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* @ addtogroup BatteryModule Battery Module
* @ brief Measures battery voltage and current
* Updates the FlightBatteryState object
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* @ {
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*
* @ file battery . c
* @ author The OpenPilot Team , http : //www.openpilot.org Copyright (C) 2010.
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* @ brief Module to read the battery Voltage and Current periodically and set alarms appropriately .
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*
* @ see The GNU Public License ( GPL ) Version 3
*
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/*
* This program is free software ; you can redistribute it and / or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation ; either version 3 of the License , or
* ( at your option ) any later version .
*
* This program is distributed in the hope that it will be useful , but
* WITHOUT ANY WARRANTY ; without even the implied warranty of MERCHANTABILITY
* or FITNESS FOR A PARTICULAR PURPOSE . See the GNU General Public License
* for more details .
*
* You should have received a copy of the GNU General Public License along
* with this program ; if not , write to the Free Software Foundation , Inc . ,
* 59 Temple Place , Suite 330 , Boston , MA 02111 - 1307 USA
*/
/**
* Output object : FlightBatteryState
*
* This module will periodically generate information on the battery state .
*
* UAVObjects are automatically generated by the UAVObjectGenerator from
* the object definition XML file .
*
* Modules have no API , all communication to other modules is done through UAVObjects .
* However modules may use the API exposed by shared libraries .
* See the OpenPilot wiki for more details .
* http : //www.openpilot.org/OpenPilot_Application_Architecture
*
*/
# include "openpilot.h"
# include "flightbatterystate.h"
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# include "flightbatterysettings.h"
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# include "hwsettings.h"
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//
// Configuration
//
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# define SAMPLE_PERIOD_MS 500
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// Private types
// Private variables
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static bool batteryEnabled = false ;
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// THESE COULD BE BETTER AS SOME KIND OF UNION OR STRUCT, BY WHICH 4 BITS ARE USED FOR EACH
// PIN VARIABLE, ONE OF WHICH INDICATES SIGN, AND THE OTHER 3 BITS INDICATE POSITION. THIS WILL
// WORK FOR QUITE SOMETIME, UNTIL MORE THAN 8 ADC ARE AVAILABLE. EVEN AT THIS POINT, THE STRUCTURE
// CAN SIMPLY BE MODIFIED TO SUPPORT 15 ADC PINS, BY USING ALL AVAILABLE BITS.
static int8_t voltageADCPin = - 1 ; // ADC pin for voltage
static int8_t currentADCPin = - 1 ; // ADC pin for current
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// Private functions
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static void onTimer ( UAVObjEvent * ev ) ;
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/**
* Initialise the module , called on startup
* \ returns 0 on success or - 1 if initialisation failed
*/
int32_t BatteryInitialize ( void )
{
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# ifdef MODULE_BATTERY_BUILTIN
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batteryEnabled = true ;
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# else
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uint8_t optionalModules [ HWSETTINGS_OPTIONALMODULES_NUMELEM ] ;
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HwSettingsOptionalModulesGet ( optionalModules ) ;
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if ( ( optionalModules [ HWSETTINGS_OPTIONALMODULES_BATTERY ] = = HWSETTINGS_OPTIONALMODULES_ENABLED ) ) {
batteryEnabled = true ;
} else {
batteryEnabled = false ;
}
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# endif
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uint8_t adcRouting [ HWSETTINGS_ADCROUTING_NUMELEM ] ;
HwSettingsADCRoutingGet ( adcRouting ) ;
// Determine if the battery sensors are routed to ADC pins
for ( int i = 0 ; i < HWSETTINGS_ADCROUTING_NUMELEM ; i + + ) {
if ( adcRouting [ i ] = = HWSETTINGS_ADCROUTING_BATTERYVOLTAGE ) {
voltageADCPin = i ;
}
if ( adcRouting [ i ] = = HWSETTINGS_ADCROUTING_BATTERYCURRENT ) {
currentADCPin = i ;
}
}
// Don't enable module if no ADC pins are routed to the sensors
if ( voltageADCPin < 0 & & currentADCPin < 0 ) {
batteryEnabled = false ;
}
// Start module
if ( batteryEnabled ) {
FlightBatteryStateInitialize ( ) ;
FlightBatterySettingsInitialize ( ) ;
static UAVObjEvent ev ;
memset ( & ev , 0 , sizeof ( UAVObjEvent ) ) ;
EventPeriodicCallbackCreate ( & ev , onTimer , SAMPLE_PERIOD_MS / portTICK_RATE_MS ) ;
}
return 0 ;
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}
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MODULE_INITCALL ( BatteryInitialize , 0 ) ;
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# define HAS_SENSOR(x) batterySettings.SensorType[x] == FLIGHTBATTERYSETTINGS_SENSORTYPE_ENABLED
static void onTimer ( __attribute__ ( ( unused ) ) UAVObjEvent * ev )
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{
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static FlightBatteryStateData flightBatteryData ;
FlightBatterySettingsData batterySettings ;
FlightBatterySettingsGet ( & batterySettings ) ;
static float dT = SAMPLE_PERIOD_MS / 1000.0f ;
float energyRemaining ;
// calculate the battery parameters
if ( voltageADCPin > = 0 ) {
flightBatteryData . Voltage = ( ( float ) PIOS_ADC_PinGet ( voltageADCPin ) ) * batterySettings . SensorCalibrations [ FLIGHTBATTERYSETTINGS_SENSORCALIBRATIONS_VOLTAGEFACTOR ] ; // in Volts
} else {
flightBatteryData . Voltage = 1234 ; // Dummy placeholder value. This is in case we get another source of battery current which is not from the ADC
}
if ( currentADCPin > = 0 ) {
flightBatteryData . Current = ( ( float ) PIOS_ADC_PinGet ( currentADCPin ) ) * batterySettings . SensorCalibrations [ FLIGHTBATTERYSETTINGS_SENSORCALIBRATIONS_CURRENTFACTOR ] ; // in Amps
if ( flightBatteryData . Current > flightBatteryData . PeakCurrent ) {
flightBatteryData . PeakCurrent = flightBatteryData . Current ; // in Amps
}
} else { // If there's no current measurement, we still need to assign one. Make it negative, so it can never trigger an alarm
flightBatteryData . Current = - 0.1234f ; // Dummy placeholder value. This is in case we get another source of battery current which is not from the ADC
}
flightBatteryData . ConsumedEnergy + = ( flightBatteryData . Current * dT * 1000.0f / 3600.0f ) ; // in mAh
// Apply a 2 second rise time low-pass filter to average the current
float alpha = 1.0f - dT / ( dT + 2.0f ) ;
flightBatteryData . AvgCurrent = alpha * flightBatteryData . AvgCurrent + ( 1 - alpha ) * flightBatteryData . Current ; // in Amps
/*The motor could regenerate power. Or we could have solar cells.
In short , is there any likelihood of measuring negative current ? If it ' s a bad current reading we want to check , then
it makes sense to saturate at max and min values , because a misreading could as easily be very large , as negative . The simple
sign check doesn ' t catch this . */
////sanity checks
// if (flightBatteryData.AvgCurrent<0) flightBatteryData.AvgCurrent=0.0f;
// if (flightBatteryData.PeakCurrent<0) flightBatteryData.PeakCurrent=0.0f;
// if (flightBatteryData.ConsumedEnergy<0) flightBatteryData.ConsumedEnergy=0.0f;
energyRemaining = batterySettings . Capacity - flightBatteryData . ConsumedEnergy ; // in mAh
if ( flightBatteryData . AvgCurrent > 0 ) {
flightBatteryData . EstimatedFlightTime = ( energyRemaining / ( flightBatteryData . AvgCurrent * 1000.0f ) ) * 3600.0f ; // in Sec
} else {
flightBatteryData . EstimatedFlightTime = 9999 ;
}
// generate alarms where needed...
if ( ( flightBatteryData . Voltage < = 0 ) & & ( flightBatteryData . Current < = 0 ) ) {
// FIXME: There's no guarantee that a floating ADC will give 0. So this
// check might fail, even when there's nothing attached.
AlarmsSet ( SYSTEMALARMS_ALARM_BATTERY , SYSTEMALARMS_ALARM_ERROR ) ;
AlarmsSet ( SYSTEMALARMS_ALARM_FLIGHTTIME , SYSTEMALARMS_ALARM_ERROR ) ;
} else {
// FIXME: should make the timer alarms user configurable
if ( flightBatteryData . EstimatedFlightTime < 30 ) {
AlarmsSet ( SYSTEMALARMS_ALARM_FLIGHTTIME , SYSTEMALARMS_ALARM_CRITICAL ) ;
} else if ( flightBatteryData . EstimatedFlightTime < 120 ) {
AlarmsSet ( SYSTEMALARMS_ALARM_FLIGHTTIME , SYSTEMALARMS_ALARM_WARNING ) ;
} else {
AlarmsClear ( SYSTEMALARMS_ALARM_FLIGHTTIME ) ;
}
// FIXME: should make the battery voltage detection dependent on battery type.
/*Not so sure. Some users will want to run their batteries harder than others, so it should be the user's choice. [KDS]*/
if ( flightBatteryData . Voltage < batterySettings . VoltageThresholds [ FLIGHTBATTERYSETTINGS_VOLTAGETHRESHOLDS_ALARM ] ) {
AlarmsSet ( SYSTEMALARMS_ALARM_BATTERY , SYSTEMALARMS_ALARM_CRITICAL ) ;
} else if ( flightBatteryData . Voltage < batterySettings . VoltageThresholds [ FLIGHTBATTERYSETTINGS_VOLTAGETHRESHOLDS_WARNING ] ) {
AlarmsSet ( SYSTEMALARMS_ALARM_BATTERY , SYSTEMALARMS_ALARM_WARNING ) ;
} else {
AlarmsClear ( SYSTEMALARMS_ALARM_BATTERY ) ;
}
}
FlightBatteryStateSet ( & flightBatteryData ) ;
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}
/**
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* @ }
*/
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/**
* @ }
*/