The present disclosure relates to monitoring battery state of health in applications such as on-board an electric vehicle.
The research and development of electric vehicles (EVs) have been accelerated at unprecedented pace in recent years, driven primarily by their energy efficiency and environmental benefits. At local level, EVs do not emit any pollutants or consume any gasoline, and in combination with electricity from renewable energy, they could achieve low emission and fuel consumption on a well-to-wheel basis. Nevertheless, despite the numerous advantages of EVs over internal combustion engine (ICE) based conventional vehicles, the performance of EVs is still limited due to the challenges in the development of reliable, low cost and long life cycle battery systems.
While scientists are continuously looking for new materials to build next-generation batteries with even higher energy and power density, there are many difficulties to be solved for the battery management and system integration. The two most important tasks are known as the state-of-charge (SOC) estimation and state-of-health (SOH) determination, and both have been studied extensively in the literature. SOC is commonly defined as “the percentage of the maximum possible charge that is present inside a rechargeable battery” and SOH is “a ‘measure’ that reflects the general condition of a battery and its ability to deliver the specified performance in comparison with a fresh battery”. Typically the quantitative definition of SOH is based either on the battery capacity or the internal resistance depending on specific applications.
Many methods for on-line SOC estimation have been studied including coulomb counting, open circuit voltage-SOC (OCV-SOC) mapping and model based approach with extended Kalman filter (EKF). In contrast, the development of an on-line SOH monitoring technique is more challenging because of the complicated electrochemical mechanism involved in battery aging. Whereas it is possible to assess the resistance growth issue by both off-line test such as electrochemical impedance spectroscopy (EIS) and on-line identification algorithms such as the use of least squares method, the detection of capacity fading still largely relies on laboratory measurements and off-line analysis.
One conventional and most common method in determining battery capacity fading is based on the OCV-SOC curve. However, it requires fully charging or discharging the battery at low rate (e.g., 1/25C) or measuring the open circuit voltage after a long relaxation period (e.g., more than 2 hours) at SOC levels that span the entire range. Both methods require time-consuming tests and thus are not applicable for on-board implementation with real-life operation data. An alternative approach of studying capacity loss is the so-called incremental capacity analysis (ICA). ICA transforms voltage plateaus, which is related to a first-order phase transformation, or inflection points, which is associated with a formation of solid solution, on charging/discharging voltage (V-Q) curve into clearly identifiable dQ/dV peaks on incremental capacity (IC) curve. The concept of ICA originally came from the intercalation process of lithium and the corresponding staging phenomenon at the graphite anode. ICA has the advantage to detect a gradual change in cell behavior during a life-cycle test, with greater sensitivity than those based on conventional charge/discharge curves and yield key information on the cell behavior associated with its electrochemical properties. Although ICA was proved to be an effective tool for analyzing battery capacity fading, most studies have focused on understanding the electrochemical aging mechanism and no study has been reported on the real-time application of ICA. Meanwhile, since all the peaks on an IC curve lie within the voltage plateau region of the V-Q curve, which is relatively flat and more sensitive to measurement noise, calculating dQ/dV directly from data set could be difficult. Hence, effective and robust algorithms of obtaining the IC curve need to be developed.
This section provides background information related to the present disclosure which is not necessarily prior art.
This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features.
In one embodiment, a method is provided for monitoring state of health of a battery. The method includes: defining a model for a battery, where the model relates terminal voltage of the battery to charged capacity of the battery in terms of unknown parameters; measuring voltage of the battery through a range of states of charge, where the range excludes the battery being fully charged and fully discharged; determining the parameters of the model by fitting the voltage measures to the model; determining an incremental capacity curve for the battery by taking derivative of the model; and identifying a peak of the incremental capacity curve, where the magnitude of the peak corresponds to a state of health for the battery. It is envisioned that the voltage measures may be taken during one of charging or discharging of the battery. Depending on the chemistry of the target battery, the range may vary between thirty percent and eighty percent.
In one aspect, the battery model is defined in accordance with support vector regression.
In another aspect, the parameters of the model are determined using a linear programming method or a least square method.
In another embodiment, a method is provided for determining capacity of a battery. The method includes: defining a model for a battery, where the model relates terminal voltage of the battery to charged capacity of the battery; receiving a plurality of voltage measures of the battery, where the voltage measures are taken through a range of states of charge and the range excludes the battery being fully charged and fully discharged; determining the parameters of the model by fitting the plurality of voltage measures to the model; determining an incremental capacity curve for the battery by taking derivative of the model; and quantifying a peak of the incremental capacity curve to thereby determine a capacity of the battery.
In yet another embodiment, a battery monitoring device is provided. The battery monitoring device includes: a data store for storing a model for a battery, and a battery monitor interfaced with a battery to measure voltage of the battery through a range of states of charge. The battery monitor determines the parameters of the model by fitting voltage measures from the battery to the model, determines an incremental capacity curve for the battery by taking derivative of the model, and quantifies a peak of the incremental capacity curve to thereby determine a capacity of the battery. In some instances, the battery monitor is implemented by computer executable instructions executed by a computer processor.
Further areas of applicability will become apparent from the description provided herein. The description and specific examples in this summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.
Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings.
Example embodiments will now be described more fully with reference to the accompanying drawings.
ICA has the advantage to detect a gradual change in cell behavior during a life-cycle test, with greater sensitivity than those based on conventional charge/discharge curves and yield key information on the cell behavior associated with its electrochemical properties. As illustrated by
Because of measurement noise, performing the ICA directly from the measured V-Q curve has proven to be not a viable option, especially for on-board BMS, where the measurement precision is limited, it is required to develop appropriate data processing functions so that ICA can be applied.
Several numerical procedures have been developed and evaluated for extracting the IC curves from battery V-Q data. While the ICA results are sensitive to the selection of curve fitting method, the support vector regression (SVR) approach with the Gaussian radial basis function (rbf) kernel is shown to be the most robust and effective method. The use of support vector regression (SVR) to represent the V-Q relation and then using analytic derivative to obtain the IC curve provides the most consistent identification results with moderate computational load.
As discussed above, SVR was chosen for battery V-Q curve identification because of its demonstrated potential in the realm of nonlinear system identification. Let x=q,y=v be the input and output of the SVR model, where q represents the battery charged capacity, v is the measured voltage. The SVR model for the V-Q curve can thereby be represented as
y=Σi=1NβiK(xi,x)+μ (1)
where N is the number of data points in the data set, βis and μ are the model parameters, whose values are determined based on the data set, and K(⋅,⋅) is the selected kernel. In this study, the rbf kernel is used and is expressed as
where τ is the adjustable parameter for the kernel function.
In one example embodiment, the parameters used in model (1) are identified by solving a convex quadratic programming (QP) problem. Through the QP-SVR and appropriate selected kernel, the flatness property is enforced in both the feature space and input space. Conventional QP-SVR has been successfully applied in identifying nonlinear dynamic systems. However, the implementation of QP-SVR may not guarantee sufficient model sparsity. LP-SVR that employs l1 norm as regularizer was then proposed to improve the model sparsity and computational efficiency LP was used as the optimization engine to derive the SVR model.
The SVR using l1 regularizer formulates the optimization problem as follows,
whereas ξn+s and ξn−s are the slack variables introduced to cope with infeasible constraints, w is the weighting factor, £ is the precision parameter, ∥⋅∥1 denotes the l1 norm in coefficient space and β is defined as β=(β1, . . . , βN)T. The optimal result usually gives zero value for most of the βis and the xis corresponding to non-zero βis are called SVs.
In order to establish the problem as an LP optimization, the coefficients βis need to be decomposed (using the property of linear piecewise convex function minimization) as,
βi=αi+−αi− |βi|=αi++αi− (4)
where αi+s and αi−s are nonnegative and satisfy αi+·αi−=0.
Following the derivation reported in “Linear programming support vector regression with wavelet kernel: A new approach to nonlinear dynamical system identification,” Math. Comput. Simulat., vol 79, pp 2051-2063, (2009), the SVR problem using l1 regularizer can be reformulated as a linear programming (LP) problem,
where
and I is an N×N identity matrix. K is the kernel matrix with entries defined as Kij=K(xi,xj),
The LP problem (5) is bounded and feasible by default and can always be solved using standard algorithms, such as the simplex method or the interior method.
f(xn)=Σi=1N
is obtained, where svi are the SVs identified by the LP-SVR algorithm and Nsv is the total number of SVs (Nsv<<N).
Then the IC curve can be computed from the fitted V-Q curve as follows, Using the ICA technique, battery aging information can be extracted through the changes observed from the IC peaks. Although the state of health may refer generally to either the internal resistance or capacity of the battery cell, this disclosure is primarily concerned with a measure of battery capacity.
For a battery being monitoring, the terminal voltage of the battery is measured at 102 over a range of states of charge. That is, multiple voltage measurements are taken, for example as the battery cell is being charged or discharged. In the case of a battery cell having lithium ion phosphate chemistry, the cell voltage is measured through the range of 60% to 80% state of charge; whereas, in the case of a battery cell having lithium nickel manganese cobalt chemistry, the cell voltage is measured through the range of 40% to 60% state of charge. Thus, the range may vary depending on the cell chemistry. In one embodiment, voltage measurements are taken in the range of 30% to 80% to encompass a wide variety of cell chemistries. In any case, voltage measures are not taken when the battery cell is fully charged or fully discharged and thus the range is less than the full capacity of the battery cell. Particular reference is made herein to determining capacity of a single battery cell. The method described herein has also been found to be applicable at a system level to a battery having a plurality of battery cells.
Parameters of the model are determined at 103 by fitting the voltage measures to the model. In the example embodiment, the model parameters are determined using a linear programming method as described above. It is readily understood that other optimization techniques can also be applied to determine model parameters. For example, even though LP-SVR works well for retrieving the IC curve from battery voltage measurement, it has to be applied repeatedly to different cells at different ages. For applications such as electric vehicles, which usually contain hundreds or thousands of battery cells, the extensive computational effort required for solving the LP problems could not be satisfied on-board or in real-time.
If the simple structure produced by the LP-SVR, Eqn. (8), can be generalized as a parametric model with kernel functions as the basis and the SVs invariant, for all cells under all conditions, conventional parameter estimation methods such as conditions, conventional parameter estimation methods such as a least squares method can be directly used and the computational efficiency would be greatly improved. In this case, the LP-SVR algorithm is only used for the initial model identification and parameterization, while the parameter adaptation to fit individual cell data and aging status could be achieved through linear parameter identification that does not require iterative optimization.
After solving for the model parameters, the incremental capacity curve is derived at 104 by taking the derivative of the model. The peak of the incremental capacity curve in turn correlates to the capacity of the battery. In an example embodiment, the magnitude of the peak can be used to quantify the battery capacity as indicated at 105. To do so, the magnitude of the peak of the incremental capacity curve is determined when the battery is pristine (i.e., the capacity is otherwise known to be at its maximum or at a nominal value), such that the magnitude can be determined in the same manner as described above. Subsequent determinations of the magnitude of the peak for the battery can be expressed as a ratio with a normalized value of the magnitude of the peak when the battery is pristine. This ratio or percentage represents a measure of the capacity of the battery. It is to be understood that only the relevant steps of the methodology are discussed in relation to
In order to investigate the possibility of using the SVR model as a parametric model with invariant support vectors, an LP sensitivity study, the problem (5) can be transformed into a standard LP formulation,
where
μ+ and μ− are added to ensure nonnegativity on the decision variable, s+ and s− are added to convert the inequality constraints into equality. This new formulation is equivalent to the original problem (5).
Assume that an optimal basis matrix B for the standard LP problem, where
B=(AΩ(1)AΩ(2) . . . AΩ(m)) (12)
and AΩ(1), . . . , AΩ(m) are linear independent columns chosen as the optimal basis from the constraint matrix A. Then B must satisfy the following conditions,
B−1b≥0
c−cBB−1A≥0 (13)
where cB consists of the entries in the objective vector c corresponding to the optimal basis matrix B,
cB=(cΩ(1)cΩ(2) . . . cΩ(m))T. (14)
Now consider the different LP problem (10) for a different data set that is obtained either for different cell or for the same cell at a different aging stage. In this study, the battery charging data are always sampled between the same range of charged capacity with the same rate (that is, the variable x in problem (3) does not change from cell to cell and time to time). Although this might be a limitation of the technique for on-board implementation, those data samples should be available for SOH monitoring periodically during normal operations, as the range of the charged capacity data be used is within the typical operating range of electric vehicles. Because of the sampling scheme, the matrix K and the constraint matrix A do not vary as the data set changes. In addition, the objective vector c is always kept constant. The only term that is changed is b in the constraint. Therefore, the condition, c−cBB−1A≥0, is always satisfied even when data variation occurs. The optimal condition for the original optimal basis matrix B to be satisfied by the new data set can then be reduced to,
B−1b≥0 (15)
Since the optimal basis matrix B decides the values of the SVs, it can be concluded that the SVs for the battery V-Q curve model would not change if, given B, the condition (15) is satisfied for the new data set. If (15) is satisfied for all data sets collected for different cells and at different aging stages, we call the SVs invariant, and the same SVs and basis functions can be used to represent different V-Q characteristics for different cells and at different time.
Moreover, b only depends on the variable y, which is the voltage measurement from the battery charging data. Hence the sensitivity analysis only needs to be performed with respect to y in this work, and problem (10) can be rewritten as,
The formulation shown in problem (16) is typically referred as parametric linear programming. In conventional parametric LP problems, the dependence of b on the varying parameters is usually linear. One can find the correspondence between all of the optimal basis and the varying parameters by solving systems of linear equalities. However, in the battery V-Q identification problem, the data variation is nonlinear and a proper parameterization needs to be found for characterizing the variation.
Before proceeding to more complex cases, first consider the special scenario: constant shift in the battery data. Let yi be the reference data set, and y2 be the data set with a constant shift (i.e., y2=y1+ρ).
Proposition 3.1: a constant shift in the data does not change the SVs.
Proof: Assume that the optimal solution of (16) corresponding to the data y1 is χ*, where
x*=(α*+;α*−;ξ*+;ξ*−;μ*+;μ*−;s*+;s*−;) (17)
Please note that the column vectors in B that correspond to μ+ or μ− are not related to the invariance of SVs, they can be treated independently from the rest of the basis vectors. For that reason, let {circumflex over (χ)}* and  be the submatrices of {circumflex over (χ)}* and A excluding the columns associated with μ+ or μ−, respectively. That is,
On the other hand, let
By substituting (20) and (19), the following equation is obtained,
where one should see that the change in ρ would be compensated by adjusting either μ+ or μ− without affecting the value of {circumflex over (χ)}*. The LP problems with y1 and that with y2 share the same as part of their optimal solutions. Therefore the variation in the constant term ρ does not change the SVs.
The variation in battery voltage measurement during aging could be simulated using the mechanistic battery aging model developed in Dubarry, et al's “Synthesize battery degradation modes via a diagnostic and prognostic model”, J. Power Sources, vol. 219, pp 204-216 (2012). The battery model considers the aging mechanism of both the positive and negative electrodes, and could reflect the qualitative relationship between the equilibrium potentials and battery aging status.
The capacity fading in LiFePO4 cells is mainly caused by the loss of cycable lithium at the early stages of aging. The loss of cycable lithium could be simulated by shifting the relative location of the two potential curves. The simulation results are shown in
It is observed that the relation between Vaged and Vref could be approximated by a quadratic function,
y=p2y*2+p1y*+ρ0 (22)
where p0, p1 and p2 are the parameters of the quadratic function.
The quadratic approximation (Eqn. (22)) found using the mechanistic battery aging model that relates the voltage response of the aged cell to that of a fresh new cell can be verified with the actual test data. As mentioned above, the data used in this study are collected from eight A123 APR18650 cells over a period of 18 months.
Since the characteristics of voltage variation are identified, it can then be investigated under what conditions the optimal basis computed from the reference data stays invariant when the parameters of the quadratic function vary as the cell ages. In particular, we are interested in finding the following feasible region for SV invariance. Assuming that the following problem,
has the optimal basis B, then for any pair of p1 and p2, if the corresponding b (y) satisfies B−1b(y)≥0, the pair (p1, p2) is considered feasible. Otherwise the pair is infeasible.
As discussed above (see Prop. 3.1), the variation in the constant term p0 does not affect the invariance of the SVs, and it can be ignored in solving the parametric LP problems.
Different from the general approaches for solving the conventional parametric LP problems, the dependence of b on the varying parameters p1 and p2, is nonlinear. Instead of solving systems of linear equalities, the determination of feasibility for each parameter pair (p1, p2) is done through Monte Carlo simulations. The results are shown in
On the other hand, we can find the region, where y and y* have a monotonic increasing relation, by computing
and therefore the region (marker by dashed lines in
pi≥−(2y
pi≥−(2y
From the simulation results shown in
According to the analysis performed above, the SVs should not change even when battery ages or varies for the applications.
v=Σi=1N
For on-board implementation, the estimation problem of the model parameters β and μ can be formulated as the following,
vj=θTϕj (27)
where
θ=[βT,μ]T
ϕj=[K(sv1,qj), . . . ,K(svN
β=[β1, . . . ,βN
and the parameters could be solved by the standard least squares method (LSM),
θ=(ΦTΦ)−1ΦTV, (29)
where
V=[v1, . . . ,vN]T
Φ=[ϕ1, . . . ,ϕN]T. (30)
Given that the battery (V, Q) data are collected at fixed sample of Q points, Φ in (29) is a constant matrix for all time. Therefore, the parameter θ can be simply calculated as,
θ=hTV, (31)
where
h=Φ(ΦTΦ)−1 (32)
is a constant matrix.
The computational time of using the LP-SVR and the LSM for the V-Q curve identification are compared in Table I below. The four groups of data are sampled within the same range of charged capacity but with different sampling rate, so the results of different sizes of data could also be compared. One can see that the computational time of the LSM is much less than that of the LP-SVR, and insensitive to the dimension of sampled data.
† The assessment summarized in Table 1 was performed on a laptop computer with a 32-bit Intel Core2 Duo CPU @ 2.53 GHz and 4.0 GB RAM.
Thus, the parametric battery V-Q curve model provides a more robust and computationally efficient way to obtain the IC curves from raw data measurement, without sacrificing any estimation accuracy.
In one example embodiment, the methods for determining capacity of a battery as described above are implemented in a vehicle as shown in
In another example embodiment, the methods for determining capacity of a battery as described above are implemented in a portable monitoring device. In this example, the portable monitoring device can be transported amongst different batteries. To take voltage measures, the portable monitoring device is configured with cables, for example with a pair of alligator clips, for interfacing with terminals of a battery. The portable monitoring device can further include a display integrated therein for displaying an indicator for the battery capacity.
The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting. As used herein, the singular forms “a,” “an,” and “the” may be intended to include the plural forms as well, unless the context clearly indicates otherwise. The terms “comprises,” “comprising,” “including,” and “having,” are inclusive and therefore specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. The method steps, processes, and operations described herein are not to be construed as necessarily requiring their performance in the particular order discussed or illustrated, unless specifically identified as an order of performance. It is also to be understood that additional or alternative steps may be employed.
The foregoing description of the embodiments has been provided for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure. Individual elements or features of a particular embodiment are generally not limited to that particular embodiment, but, where applicable, are interchangeable and can be used in a selected embodiment, even if not specifically shown or described. The same may also be varied in many ways. Such variations are not to be regarded as a departure from the disclosure, and all such modifications are intended to be included within the scope of the disclosure.
This application claims the benefit of U.S. Provisional Application No. 61/870,256, filed on Aug. 27, 2013. The entire disclosure of the above application is incorporated herein by reference.
This invention was made with government support under DE-PI0000012 awarded by the Department of Energy. The Government has certain rights in the invention.
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