1. Introduction
Rechargeable lithium batteries are widely used for electric vehicles (EVs) and energy storage systems (ESSs). Lithium is a very attractive material for batteries due to its low equivalent weight and high standard potential. The first lithium ion battery was introduced to the market by Sony Corporation in 1992, and the market for these has grown to several hundreds of millions of cells per year for consumer applications. Most of them are composed of a carbon negative electrode and a lithium cobalt oxide (LiCoO2) positive electrode [1]. Lithium chemistry provides higher power and energy densities in both gravimetric and volumetric terms, which makes it suitable for applications such as smart phones, digital cameras, and laptops [2]. After the lithium iron phosphate (LiFePO4) battery was introduced by replacing the expensive cathode material with LiCoO2, the cost of the battery was reduced by 10% to 50% [3]. Compared with the other phosphate-based cathode materials, LiFePO4 has lower operating voltage (2.0–3.65 V) but higher capacity [4]. The use of LiFePO4 offers a longer cycle life and a higher current rating over standard lithium ion batteries. Due to their advantages over other kinds of batteries, LiFePO4 batteries have shown a significant growth in use of EVs and ESSs. If the LiFePO4 battery is overcharged or over discharged, the battery may receive fatal damage. So, it is necessary to manage this battery so that it can be used within a safe range [5,6,7]. A battery management system (BMS) that can accurately estimate the state of charge (SOC) of the battery is also needed [8,9,10].
However, a flat Open Circuit Voltage (OCV) plateau in the range of 20% to 80% SOC makes it difficult to achieve an accurate SOC estimation [11]. LiFePO4 batteries produce a hysteresis phenomenon and cell OCV during charge that are different from during discharge at the same SOC [12]. The hysteresis phenomenon needs to be considered carefully for an accurate SOC estimation; otherwise, the error in SOC estimation becomes quite large.
In this paper, an SOC estimation with an advanced hysteresis modeling method is proposed to achieve SOC estimation of LiFePO4 batteries with high accuracy. In the proposed method, the conventional parallelogram method [13] is further improved by using piecewise linearization of the hysteresis contour to reduce approximation error in the conventional method. The SOC estimation is performed by using an extended Kalman filter (EKF) and the parameters of the equivalent circuit of LiFePO4 are estimated by the auto regressive exogenous (ARX) model and the recursive least square (RLS) filter [14,15,16]. In order to prove the effectiveness of the proposed method, accuracy in estimating SOC by each method are compared.
2. Conventional and Proposed Hysteresis Modeling Methods for LiFePO4 Battery In this section, the conventional and proposed hysteresis modeling methods are presented and their advantages and disadvantages show the superiority of the proposed method. 2.1. One-State Hysteresis Modeling Method
One conventional hysteresis modeling method for the battery is one-state hysteresis model (OSHM) [17] and is applied to a LiFePO4 battery in References [11,18]. An averaged OCVOCVavgSOCas a function of SOC is described by means of OCV charge and OCV discharge extracted from the SOC–OCV curve. The functionHSOCis the difference between the averaged OCV and the OCV charge or OCV discharge,HSOC=OCVchr−OCVavgorHSOC=OCVavg−OCVdis , as shown in Figure 1. Hence, it is positive during the charge and negative during the discharge.
Therefore, the actual OCV of the battery including the hysteresis can be represented asOCV=OCVavg+Vh, whereVhis the hysteresis voltage introduced by Equation (1)
dVhSOC,tdSOC=K·H(SOC)−VhSOC,t
where K is the constant that determines the rate of voltage change where the hysteresis voltage reachesHSOC. SincedSOCdt=ηb·IbCnby coulomb counting, Equation (1) can be rewritten as Equation (2)
dVhSOC,tdt=K·ηb.IbCnH(SOC)−VhSOC,t
whereηbis the coulombic efficiency,Ibis the charging current, andCnis the capacity of the battery.
Equation (2) can be written in discrete form by Equation (3).
Vh,k=exp−K·ηb.Ib,k−1Cn·Vh,k−1+1−exp−K·ηb.Ib,k−1Cn·HSOCk
The final form of the state space equation can be obtained by including the hysteresis voltage in Equation (3) and EKF is used for the SOC estimation. Though this method is simple to implement, it shows a large error in estimating SOC of the LiFePO4 for which the SOC–OCV curve has a flat plateau. 2.2. Hysteresis Modeling Method by Using a Parallelogram
Another conventional hysteresis modeling method is the parallelogram modeling method proposed in Reference [19]. In this method, the trajectory of the hysteresis voltage during charge/discharge is modeled by using a parallelogram and is calculated by using the charge throughput as shown in Equation (4).
OCVz, α=1−αOCVdisz+αOCVchrz
where α is the hysteresis factor.
The empirical equation of the hysteresis factor corresponding to the charge throughput can be expressed as follows [20]
α=vα1+1−vα2
For the charge, α1=∫h1ICndt0≤α1≤1α2=∫h2ICndt0≤α2≤1
For the discharge, α1=∫h1ICndt0≤α1≤1α2=∫h2ICndt0≤α2≤1
wherevis the ratio ofα1andα2;h1andh2are the slopes of the parallelogram model. All the parameters in the hysteresis model,v,h1, andh1, can be extracted by using a parallelogram and the least square estimation. It is possible to calculate the hysteresis voltage accurately by the parallelogram modeling method; hence, the SOC estimation can be achieved with high accuracy. However, the error in between the actual hysteresis voltage trajectory and the parallelogram increases since both inner and outer parallelograms cannot exactly follow the hysteresis voltage as shown in Figure 2.
2.3. The Proposed Advanced Hysteresis Model for the LiFePO4 Battery
In this section, the proposed hysteresis modeling method is described and its advantage is presented in detail. The main purpose of the hysteresis modeling is to determine whether the actual OCV at each SOC lies on the charge curve, on the discharge curve, or somewhere between them depending on the charge throughput [13]. According to the results achieved from the previous test, as depicted in Figure 3 and Figure 4, the boundary curve is called by the major loop. The partial test with 4% ∆SOC will show a small loop lying between two boundary curves, called a minor loop. As shown in Figure 3, the charge curve and the discharge curve of the minor loop touches the major loop when the SOC varies by 20%.
The proposed method was developed to reconstruct the OCV transition caused by hysteresis. This method introducesαandβas two hysteresis factors andΔ as a change in SOC. Figure 4 shows how the method works withα,β, andΔ.Δincreases from 0 toΔnwhen the battery is charged, whileΔdecreases from Δn to 0 when the battery is discharged. In order to model the hysteresis accurately, the variation in OCV between the upper boundary curve and the lower boundary curve are divided into five sectors as shown in Figure 4.αandβrepresent the ratio of hysteresis voltage change during the charge and discharge at each sector. ThoughΔcan be selected less than 4% to improve the accuracy, it incurs more computational burdens. Therefore,nis selected as 5 so that each step change results in 4% SOC variation.αrepresents the slope of the voltage change during the charge and its value varies fromα0toαn.βrepresents the slope of the voltage change during the discharge and its value varies fromβntoβ0.
Hence, the OCV during the hysteresis can be calculated according to the charge throughput as shown in the following equations.
OCVSOC,α=α·OCVchr+1−α·OCVdis
OCVSOC,β=β·OCVchr+1−β·OCVdis
where the values ofαandβare normalized between 0 to 1. The hysteresis factors are refreshed at each sector. However, when the accumulated charge throughput during the charge or discharge exceeds 20% SOC, the OCV touches the major hysteresis loop. Equations (10) and (11) show how to calculateαandβ.
αk=α0−∫0kηb.αn−αn−1·Ib,k,chrΔn−Δn−1·Cndt
βk=β0−∫0kηb.βn−βn−1·Ib,k,disΔn−Δn−1·Cndt
Equations (10) and (11) can be represented in discrete forms as Equations (12) and (13).
αk=αk−1−ηb.αn−αn−1·Ib,k,chr·ΔTΔn−Δn−1·Cn
βk=βk−1−ηb.βn−βn−1·Ib,k,dis·ΔTΔn−Δn−1·Cn
whereCnis the available capacity,ηbis the coulomb efficiency of the battery,Ib,k,chris the charge current, andIb,k,disis the discharge current.
3. SOC Estimation of LiFePO4 Battery with EKF and Parameter Estimation Using ARX Model and RLS Filter In this section the SOC estimation of LiFePO4 battery with EKF and parameter estimation using ARX model and RLS filter is detailed. 3.1. ARX Model and RLS Filter
In order to achieve a good accuracy in SOC estimation of the battery, an accurate model of the battery needs to be used. The battery model should be capable of describing the dynamic behaviors of the battery with high accuracy and it should be simple enough to establish state equations [21]. The equivalent circuit model (ECM), consisting of resistor and parallel R-C networks connected in series, is the most commonly selected model. It was identified that two R-C networks are good enough to represent the dynamic behaviors of LiFePO4 batteries including the relaxation voltage [22]. However, since the two R-C networks model is too complicated and the computational burden is quite high, the R-R||C model is preferred, as shown in Figure 5. Here, the voltage variation by the second R-C network is merged into the OCV by reconstructing it with the equilibrium voltage [23]. The ECM model used for the modeling is represented in Figure 5, in which Ri is the pure Ohmic resistance, Rp is the charge transfer resistance, and the double layer capacitance is Cp [24].
In order to estimate the SOC of the battery, the combination of the RLS and EKF is used and the parameters of the battery are obtained by the auto regressive exogenous (ARX) model in this research. The transfer function G(s) of the battery impedance can be expressed in s-domain as follows.
Gs=Vbs−OCVsIbs=VimpsIbs=Ri+Rp1+s·Rp·Cp
In order to convert this transfer function in a discrete form, Euler’s forward transformation method is used and the resulting equation can be obtained as follows.
Gz−1=a1+a2·z−11+a3·z−1
The impedance voltage in discrete form is shown in Equation (16).
Vimp,k=a1·Ib,k+a2·Ib,k−1+a3·Vimp,k−1
where a1=Ri,a2=TCp1+RiRp,a3=TRp.Cp−1, andVimp,k=OCVk−Vb,k
To identify these parameters, Equation (17) should be written in a form as
Vimp,k=θk.ψk=a1,k,a2,k,a3,kIb,k;Ib,k−1;Vimp,k−1
whereψkis the input vector obtained from the measured input values including the voltage drop across the battery impedance at the previous time indexVimp,k−1and the measured battery current at current and previous time indexIb,kandIb,k−1.
As mentioned earlier, the RLS filter is used to identify the parameters of the battery model. The RLS filter has been widely used for online parameter identification due to its lower computational burden during the last three decades [25,26]. The step-by-step implementation of this method is shown in Table 1. The dynamic system model described in Equation (17) is used and the forgetting factor λ is introduced, which gives more weight to the current data than the previous data for the time-varying vectorθk. After the vectorθkis obtained, the parameters of the battery can be determined by Equation (18).
Ri=a1, Rp=a2−a1.a31+a3, Cp=Ta2−a1.a3
Equations (16)–(18) are used to extract the battery parameters after identifyinga1,k,a2,k and a3,k . All the above-mentioned procedure is summarized in Figure 6 [19].
3.2. Extended Kalman Filter for the SOC Estimation
The SOC of the battery can be represented through the current integration as shown in Equation (19).
SOCt=SOC0+∫0tηb·IbCndt
Equation (19) can be rewritten as the discrete form as in Equation (20).
SOCk=SOCk−1+ηb·Ib,k−1·ΔtCn
The reconstructed OCV at each time index k during the charge by Equation (8) is
OCV(SOCk,hk)=hk·OCVchr(SOCk)+1−hk·OCVdis(SOCk)
whereSOCkandSOCk−1are the SOC at time index k and k − 1, respectively;Ib,k−1is the battery current at previous time index; andΔtis the sampling period.
The EKF is a method to estimate the system state in real-time and the algorithm compares the measured terminal voltage with the estimated voltage predicted by the EKF using a battery model [28]. The difference between the predicted and the measured terminal voltage leads to an adaption of the state of the battery model to that of the real battery. Therefore, the accurate model of the battery is critical for the accurate estimation of the terminal voltage, hence the SOC estimation. The discrete-time state equations for a non-linear system can be given as
xk=fxk−1,uk+wkyk=hxk,uk+vk
wherexkrepresents the state parameter,fandhare non-linear system functions,ukis the input,wkis the process noise vector,vkis measurement noise vector, andykis the measured signal.
In order to apply the EKF to the equivalent circuit model of LiFePO4 battery in Figure 5, the state space equation in the discrete form can be derived as
xk=SOCkVCp,k=1001−ΔtCp Rp·SOCk−1VCp,k−1+−ΔtCn−ΔtCp·Ib,k−1+wk−1
yk=Vb,k=OCVSOCk,αk,βk−VCp,k−Ri·Ib,k+vk−1
The computation process of the EKF with the above state space equation is well-known and it can be summarized as shown in Figure 7 [28].
4. Experimental Results 4.1. Experiments of the SOC-OCV Curve of LiFePO4
The tests were conducted on a LiFePO4 HW 38120 L/S, for which specifications are shown in Table 1, by connecting it to a bipolar DC power supply (NF BP4610). A code was composed by LabVIEW 11.0 to control the output of the power supply, and voltage and current of the battery cell under test were recorded through a data acquisition board, NI PCI-6154.
In order to obtain the SOC–OCV relationship, a charge and discharge test was conducted using variable current pulses. The magnitude and duration of the current was 0.2 C and 15 min, respectively, so that each charge and discharge step charged and discharged the battery by 5% of its capacity. After each step, 3 h relaxation with no current was applied to obtain the OCV at a certain SOC. After finishing the test, two boundary OCV curves were obtained as shown in Figure 3. As shown in Figure 3, the SOC–OCV curves of the battery during the charge and discharge were not identical due to the hysteresis phenomenon. There was a gap between two curves of which the maximum value was 45 mV.
After each current pulse, the battery took 3 h relaxation and the terminal voltage was measured to obtain 3 min and 3 h relaxation voltage,OCV3mandOCV3h , respectively. The cell voltage recovery over several minutes or hours could not be reproduced with the simple equivalent circuit model given in Figure 5. Hence, the OCV recovery effect had to be considered separately. It was assumed that the voltage dropped across the impedance of the battery model and vanished after resting 3 min and the OCV recovery remained only. In order to incorporate the OCV recovery during the rest time, recovery factorζwas introduced as shown in Equation (25). Here,ζ indicates whether the OCV is completely recovered or not and the transition from ζ = 1 to ζ = 0 during rest periods is assumed to proceed as a first-order exponential equation with the time constant of the OCV recovery [13]. Therefore, the OCV during the hysteresis lies in between them and can be modeled as a time constantτand the diffusion factor ζ can be calculated by using Equation (25).
ζ=exp180−tτ
where t is the relaxation time. If the relaxation is less than 3 min (180 s),ζis equal to 1. Therefore, the OCV can be reconstructed usingζas follows
OCVchrSOC,ζ=ζ·OCV3h,chr+1−ζ·OCV3m,chr
OCVdisSOC,ζ=ζ·OCV3h,dis+1−ζ·OCV3m,dis
whereOCVchrandOCVdisare the OCV during the charge and discharge considering the relaxation, respectively.
4.2. Experiments for the Hysteresis Curve of LiFePO4
In order to model the hysteresis, the hysteresis test had to be performed. Some partial cycles were applied to obtain hysteresis curves between two boundary OCV curves. At first, the fully charged battery was discharged to 20% SOC and charged up to 40% SOC by using five current pulses with 4% ∆SOC as shown in Figure 8. Next, the cell was discharged with the same current pulses. After each pulse the battery was rested for 3 h to obtain the OCV. The test was repeated at different SOCs such as 40% to 60% and 70% to 90% SOC to verify the hysteresis behavior. We found that the partial cycles at different SOCs were all the same, as shown in Figure 9. The hysteresis factors can be calculated for every 4% interval of the hysteresis curve from the experimental results.
4.3. Experimental Verification
To verify the proposed hysteresis modeling algorithm at different SOC regions, the battery was fully charged to 100% SOC and discharged to 20% SOC, as shown in Figure 10. Then the battery underwent the charge and discharge process repeatedly at various SOC values. This current profile applied to the battery test is suitable to verify the accuracy of the hysteresis modeling since the hysteresis phenomenon occurs at many different SOCs.
In the experiments, the Ah counting method with known initial SOC value was used as an SOC reference for the comparison. In order to confirm the performance of SOC estimation by EKF, three different initial values, 60%, 90%, and 100% SOC, were given at the beginning. Figure 10 shows the results of the SOC estimation with three different initial SOC values and Figure 11 shows the error between the results by the proposed method and the Ah counting. Though the time for the convergence of each SOC estimation with different initial value was different: all of them converged successfully within 4 h and all the SOC estimation error after the convergence did not exceed 2%, which proves the reliable performance of the proposed method.
4.4. Comparison of the Methods by SOC Estimation Error
In order to compare the performance of the SOC estimation with different hysteresis modeling methods, each method was implemented separately and the results are compared in Figure 12. The root mean square error (RMSE) in Equation (28), mean absolute error (MAE) in Equation (29), and maximum error were used to evaluate the effectiveness of estimation. Here, MAE shows the size of the error intuitively and RMSE shows the distribution of the error
RMSE=∑k=1n ek2n
MAE=∑k=1nekn
whereekis the SOC estimation error at time index k.
The SOC estimation errors with three different hysteresis models are summarized in Table 2.
The results in Figure 12 and Table 2 indicate that the SOC estimation by the proposed hysteresis model shows the lowest RMSE, MAE and maximum error, thereby proving the superior performance of the proposed hysteresis modeling method.
5. Conclusions In this study, the hysteresis phenomenon of a LiFePO4 battery was investigated and an advanced hysteresis modeling method was proposed. The validity of the proposed hysteresis modeling was verified through the comparison of the SOC estimation errors with the other two conventional methods. Due to the precise modeling of the hysteresis phenomenon in LiFePO4 battery, the SOC estimation can be achieved with higher accuracy. The proposed hysteresis modeling can also be applied to the SOC estimation of other batteries, such as a lead-acid battery, which exhibits a significant hysteresis phenomenon.
Enlarge this image.Figure 1. State of charge (SOC-OCV) curve of LiFePO4 and H(SOC) curve for one-state hysteresis modeling (OSHM).
Enlarge this image.Figure 6. Parameter identification procedure using recursive least square filter and auto regressive exogenous (ARX) model.
| Name | Cylindrical LiFePO4 Battery | Model | HW 38120 L/S |
|---|---|---|---|
| Nominal Capacity | 10,000 mAh | Rated Voltage | 3.2 V |
| Energy Density | 105 Wh/kg | Internal Resistance | ≤8 mΩ |
| Max. charging current | 3 C (30 A) | Recommended charging current | 0.5 C, 5 A × 2 h |
| Max. continuous discharging current | 3 C (30 A)–10 C (100 A) | Recommended discharging current | 1 C (10 A) |
| Standard. charging voltage | 3.65 ± 0.05 V | Max. End-off discharged voltage | 2.0 V |
| Model | Proposed Model | Parallelogram Model | OSHM |
|---|---|---|---|
| RMSE | 0.69% | 0.87% | 1.51% |
| MAE | 0.47% | 0.66% | 0.95% |
| Max. Error | 2.02% | 2.50% | 5.01% |
Author Contributions
Y.K. wrote the manuscript, designed the algorithm of proposed method, analyzed the algorithm of the proposed method, and helped in preparing the final manuscript.; W.C. reviewed the manuscript and supervised the research. Both authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Acknowledgments
This research received no support.
Conflicts of Interest
The authors declare no conflict of interest.
Abbreviations
The following abbreviations are used in this manuscript:
| SOC | state of charge |
| BMS | battery management system |
| EVs | electric vehicles |
| ESSs | energy storage systems |
| EKF | extended Kalman filter |
| ARX | auto regressive exogeneous |
| RLS | recursive least square |
| LiFePO4 | lithium iron phosphate |
| LiCoO2 | lithium cobalt oxide |
| OSHM | one state hysteresis model |
| ECM | equivalent circuit model |
| RMSE | root mean square |
| MAE | mean absolute error |
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Younghwi Ko
and
Woojin Choi
*
Department of Electrical Engineering, Soongsil University, Seoul 06978, Korea
*Author to whom correspondence should be addressed.
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