/usr/include/ns3.17/ns3/li-ion-energy-source.h is in libns3-dev 3.17+dfsg-1build1.
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/*
* Copyright (c) 2010 Andrea Sacco
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation;
*
* 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
*
* Author: Andrea Sacco <andrea.sacco85@gmail.com>
*/
#ifndef LI_ION_ENERGY_SOURCE_H
#define LI_ION_ENERGY_SOURCE_H
#include "ns3/traced-value.h"
#include "ns3/energy-source.h"
#include "ns3/nstime.h"
#include "ns3/event-id.h"
namespace ns3 {
/**
* \ingroup energy
* \brief Model a generic Lithium Ion Battery basing on [1][2].
*
* The model can be fitted to any type of Li-Ion Battery, simply changing the
* model parameters.
* The default values are fitted for the Panasonic CGR18650DA Li-Ion Battery [3].
*
* The energy is drained as defined from the EnergySource interface but, this class
* consider the non-linear behaviour of Li-Ion cell. Each time energy is drained from
* the cell, the class evaluates the discharge curve to get the actual cell's voltage,
* accordingly to State of Charge (SOC) and current's drain.
*
* If the actual voltage of the cell goes below the minimum threshold voltage, the
* cell is considered depleted and the energy drained event fired up.
*
*
* The model requires several parameters to approximates the discharge curves:
* - IntialCellVoltage, maximum voltage of the fully charged cell
* - NominalCellVoltage, nominal cell's voltage, is used to determine the end of the
* nominal zone.
* - ExpCellVoltage, cell's voltage at the end of the exponential zone
* - RatedCapacity, rated capacity of the cell, in Ah
* - NomCapacity, cell's capacity at the end of the nominal zone, in Ah
* - ExpCapacity, cell's capacity at the end of the exponential zone, in Ah
* - InternalResistance, internal resistance of the cell, in Ohms
* - TypCurrent, typical discharge current value, used during the fitting process, in Ah
* - ThresholdVoltage, minimum threshold voltage below which the cell is considered
* depleted
*
* For a complete reference of the energy source model and model's fitting please refer
* to <a href="http://www.nsnam.org/wiki/index.php/GSOC2010UANFramework">UAN Framework</a>
* page and <a href="http://www.nsnam.org/wiki/index.php/Li-Ion_model_fitting">Li-Ion model
* fitting</a> page.
*
* References:
* [1] C. M. Shepherd, "Design of Primary and Secondary Cells - Part 3. Battery discharge equation," U.S. Naval Research Laboratory, 1963
* [2] Tremblay, O.; Dessaint, L.-A.; Dekkiche, A.-I., "A Generic Battery Model for the Dynamic Simulation of Hybrid Electric Vehicles," Ecole de Technologie Superieure, Universite du Quebec, 2007
* [3] http://www.panasonic.com/industrial/includes/pdf/Panasonic_LiIon_CGR18650DA.pdf
*
*/
class LiIonEnergySource : public EnergySource
{
public:
static TypeId GetTypeId (void);
LiIonEnergySource ();
virtual ~LiIonEnergySource ();
/**
* \return Initial energy stored in energy source, in Joules.
*
* Implements GetInitialEnergy.
*/
virtual double GetInitialEnergy (void) const;
/**
* \param initialEnergyJ Initial energy, in Joules
*
* Implements SetInitialEnergy. Note that initial energy is assumed to be set
* before simulation starts and is set only once per simulation.
*/
void SetInitialEnergy (double initialEnergyJ);
/**
* \returns Supply voltage at the energy source.
*
* Implements GetSupplyVoltage.
*/
virtual double GetSupplyVoltage (void) const;
/**
* \param supplyVoltageV Initial Supply voltage at the energy source, in Volts.
*
* Sets the initial supply voltage of the energy source.
* To be called only once.
*/
void SetInitialSupplyVoltage (double supplyVoltageV);
/**
* \return Remaining energy in energy source, in Joules
*
* Implements GetRemainingEnergy.
*/
virtual double GetRemainingEnergy (void);
/**
* \returns Energy fraction.
*
* Implements GetEnergyFraction.
*/
virtual double GetEnergyFraction (void);
/**
* \param energyJ Amount of energy (in Joules) to decrease from energy source.
*
* Implements DecreaseRemainingEnergy.
*/
virtual void DecreaseRemainingEnergy (double energyJ);
/**
* \param energyJ Amount of energy (in Joules) to increase from energy source.
*
* Implements IncreaseRemainingEnergy.
*/
virtual void IncreaseRemainingEnergy (double energyJ);
/**
* Implements UpdateEnergySource.
*/
virtual void UpdateEnergySource (void);
/**
* \param interval Energy update interval.
*
* This function sets the interval between each energy update.
*/
void SetEnergyUpdateInterval (Time interval);
/**
* \returns The interval between each energy update.
*/
Time GetEnergyUpdateInterval (void) const;
private:
void DoInitialize (void);
void DoDispose (void);
/**
* Handles the remaining energy going to zero event. This function notifies
* all the energy models aggregated to the node about the energy being
* depleted. Each energy model is then responsible for its own handler.
*/
void HandleEnergyDrainedEvent (void);
/**
* Calculates remaining energy. This function uses the total current from all
* device models to calculate the amount of energy to decrease. The energy to
* decrease is given by:
* energy to decrease = total current * supply voltage * time duration
* This function subtracts the calculated energy to decrease from remaining
* energy.
*/
void CalculateRemainingEnergy (void);
/**
* \param current the actual discharge current value.
*
* Get the cell voltage in function of the discharge current.
* It consider different discharge curves for different discharge currents
* and the remaining energy of the cell.
*/
double GetVoltage (double current) const;
private:
double m_initialEnergyJ; // initial energy, in Joules
TracedValue<double> m_remainingEnergyJ; // remaining energy, in Joules
double m_drainedCapacity; // capacity drained from the cell, in Ah
double m_supplyVoltageV; // actual voltage of the cell
EventId m_energyUpdateEvent; // energy update event
Time m_lastUpdateTime; // last update time
Time m_energyUpdateInterval; // energy update interval
double m_eFull; // initial voltage of the cell, in Volts
double m_eNom; // nominal voltage of the cell, in Volts
double m_eExp; // cell voltage at the end of the exponential zone, in Volts
double m_internalResistance; // internal resistance of the cell, in Ohms
double m_qRated; // rated capacity of the cell, in Ah
double m_qNom; // cell capacity at the end of the nominal zone, in Ah
double m_qExp; // capacity value at the end of the exponential zone, in Ah
double m_typCurrent; // typical discharge current used to fit the curves
double m_minVoltTh; // minimum threshold voltage to consider the battery depleted
};
} // namespace ns3
#endif /* LI_ION_ENERGY_SOURCE_H */
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