CN112234673A - Battery energy balancing method suitable for balancing circuit - Google Patents

Abstract

The invention discloses a battery energy balancing method suitable for a balancing circuit, relates to the technical field of battery energy, and provides a balancing control algorithm which adopts an AUKF algorithm to improve SOC estimation precision and solves the problem of possible overcharge and overdischarge damages to a battery when only the SOC is used as a parameter of the balancing control algorithm. The fuzzy neural network designed by the invention is a first-order T-S fuzzy neural network, 5 parameters in total of a front part parameter and a back part parameter are required to be determined through learning, the learning algorithm adopts a hybrid algorithm of a BP algorithm and a least square method, the front part parameter is determined through the BP algorithm, and the back part parameter is determined through the least square method. And training the fuzzy neural network through data in the database, and identifying to obtain all parameters.

Description

Battery energy balancing method suitable for balancing circuit

Technical Field

The invention relates to the technical field of battery energy, in particular to a battery energy balancing method suitable for a balancing circuit.

Background

In recent years, electric vehicles have been rapidly developed, and batteries for supplying energy to the electric vehicles naturally receive wide attention from researchers. The types of batteries used by electric vehicles are various, and among them, lithium batteries have become the mainstream battery type used by electric vehicles due to the advantages of good power performance, long cycle life, high energy density, no memory effect and the like. However, the parameters of the single lithium battery, such as the capacitance, the voltage and the instantaneous discharge power, are far from the parameters required by the design of the electric automobile. Therefore, to meet the requirements of electric vehicles, hundreds of single batteries are required to be combined into a battery pack in a series or parallel manner.

Unfortunately, the series-parallel connection of the unit cells creates a new problem of charge imbalance, and the charge imbalance is more pronounced in the series-connected battery pack. The imbalance of the charge amount causes the reduction of the comprehensive performance of the battery, the service life of the battery pack is greatly shortened, and the secondary explosion occurs. Researchers have found that the initial cause of the charging imbalance is due to manufacturing variability resulting in subtle cell-to-cell variability that is amplified during cell cycling. The production difference of the battery cannot be eliminated by applying the technology, and the unbalance of the battery charging can be improved only by utilizing the equalization technology in the use process of the battery.

The essence of the equalization technology is that the charged difference is eliminated to a certain extent through an equalization circuit and an equalization control algorithm. The equalization technology can be divided into a passive equalization technology and an active equalization technology according to two different ways of energy consumption and energy transfer. At present, the SOC is mostly adopted by the equalization algorithm to reflect the state of charge of the battery, and if the SOC can accurately reflect the state of charge of the battery, the performance of the control algorithm with the SOC as the only discrimination parameter can meet the actual requirement. However, when the battery is discharged in a low state, the voltage drop of the battery will increase rapidly, and when the battery is discharged with a large current, if the battery is not provided with the minimum voltage limiting protection, the battery will be in an overdischarge state for a long time, which may cause damage to the battery. Similarly, when the battery is discharged to a high state of charge, the voltage rise of the battery increases, and when the battery is charged with a large current, the battery is easily overcharged for a long time, and the battery is damaged. In addition, when the battery is severely aged, the polarization effect and the ohmic effect of the battery are more remarkable, and the voltage drop of the battery in a low-charge state and the voltage rise of a high-charge state are more obvious.

In order to solve the problems, the application provides a battery energy balancing method suitable for a balancing circuit, and solves the problem that overcharge and overdischarge damage to a battery can be caused when only SOC is used as a parameter of a balancing control algorithm.

Disclosure of Invention

The invention aims to provide a battery energy balancing method suitable for a balancing circuit, which solves the problem of possible overcharge and overdischarge damages to a battery when only SOC is used as a parameter of a balancing control algorithm.

The invention provides a battery energy balancing method suitable for a balancing circuit, which comprises the following steps:

s1: collecting the voltage and current of the equalizing circuit;

s2: establishing a second-order equivalent circuit model, and estimating the SOC by using an AUKF algorithm;

s3: calculating the difference value of the SOC of different batteries, and judging whether the conditions of one low or one high or one low exist;

s4: establishing a neural network, and if the situation described in the step S3 exists, taking the terminal voltage as the input of the neural network, and determining whether the output equalization current value reaches an equalization threshold value;

s5: if the situation described in the step S3 does not exist, calculating an average value of the SOC of each battery, and determining whether the average value is between 0.2 and 0.8, and if so, determining whether the output equalization current value reaches an equalization threshold value by using the SOC as an input of the neural network; if the voltage is not between 0.2 and 0.8, the terminal voltage is used as the input of the neural network, and whether the output equalization current value reaches the equalization threshold value is judged;

s6: and when the output equalization current value reaches an equalization threshold value, the battery energy is equalized.

Further, the second-order equivalent circuit model in step S2 describes the concentration polarization effect and the electrochemical polarization effect by using 2 RC networks, respectively, and according to KCL and KVL laws, a circuit state expression can be obtained as follows:

U_O(t)＝R_OI(t) (1)

wherein, U_O(t) is the ohmic voltage of the voltage,U_e(t) electrochemical polarization voltage, U_d(t) is concentration polarization voltage;

U(t)＝U_OCV(t)+U_O(t)+U_e(t)+U_d(t) (4)

wherein U (t) is the battery terminal voltage;

obtaining an expression of the change of the SOC of the battery along with time by using a current integration method:

therein, SOC₀Is an initial SOC, Q_NThe standard capacitance of the battery is used, and eta is the charge-discharge efficiency of the battery;

discretization of formulae (2), (3) and (5) gives:

wherein, tau is a sampling period, tau_e＝R_eC_e，τ_d＝R_dC_d；

A discretized state space observation equation is established by equations (6), (7) and (8), as follows:

wherein w (k-1) is the observation noise of the model;

the discretized state output equation of the model is shown in equation (10):

U(k)＝U_OCV(k)+U_O(k)+U_e(k)+U_d(k)+v(k-1) (10)

where v (k-1) is the observation noise of the terminal voltage.

Further, the AUKF algorithm in step S2 first constructs sampling points, and the state vector X (k) is composed of state variables SOC (k), U_e(k) And U_d(k) The composition is expressed as follows:

X(k)＝[SOC(k) U_e(k) U_d(k)]^T (11)

further, the step of estimating the SOC by using the AUKF algorithm in step S2 includes:

s21: initializing a nonlinear system:

s22: constructing 2n +1 sampling point sets and carrying out nonlinear conversion:

s23: the weight in the iterative calculation process is calculated as follows:

wherein the content of the first and second substances,

for a scale parameter, α represents the sampling point at

Distribution of the surroundings, i.e. 1>α>e^-4；

Generally takes on a value of

Beta is used to integrate X prior estimates, generally chosen to be 2; w_i ^(m)And W_i ^(c)Respectively calculating the weighted factors used for the mean value and the covariance of the ith sampling point;

s24: the one-step prediction for computing the 2n +1 sample point sets is:

Xⁱ(k-1)＝f(X_i,k-1),i＝0,1,…2n (16)

s25: the time update in the AUKF algorithm is:

s26: the measurements in the AUKF algorithm are updated as:

s27: the battery state variables and covariance are estimated as:

s28: adaptive law covariance matching:

where q (k) is the covariance of the model noise w (k), and r (k) is the covariance of the terminal voltage measurements v (k).

Further, the neural network in step S4 includes: the fuzzy rule strength normalization layer comprises a fuzzy layer, a fuzzy rule strength release layer, a rule strength normalization layer, a fuzzy rule output layer and an output layer.

Further, the input amount of the blurring layer is 2, which are the SOC difference value and the SOC average value, and can be expressed as:

therein, SOC_iThe SOC value, SOC, of the ith battery in the m single batteries on the left side of the equalizing unit_jThe SOC value of the jth battery in the n batteries at the right side of the equalizing unit is shown, delta SOC represents the difference value of the average values of the SOC at the left side and the right side of the equalizing unit, and SOC_avgRepresents the average value of the SOC on both sides of the equalizing unit;

defining the universe of the two input quantities according to the selected battery characteristics and respectively named A and B, wherein the universe of the two input quantities delta SOC of the SOC-based fuzzy neural network is [0,0.6 ]]，SOC_avgHas a discourse field of [0,1](ii) a Delta V in two input quantities of the fuzzy neural network based on terminal voltage is [0,1]，V_avgIs [2.6,4.2 ]](ii) a Considering the unbalanced state and the battery characteristics of the battery pack, dividing discourse domains of two input quantities into 5 fuzzy sets which are VS, S, M, L and VL respectively, and determining the membership function number of each input quantity; the membership function types are all Gaussian functions and are expressed as follows:

wherein a is the center of the membership function, b is the width of the membership function, and a and b are used as the front part parameters of the fuzzy neural network and are obtained by database training and learning;

input quantities delta SOC/delta V and SOC_avg/V_avgAre respectively defined as x₁And x₂: and obtaining an input and output expression of the first layer:

wherein the content of the first and second substances,

is an input quantity x₁The ith membership function of (a),

is a number x₂The jth membership function of (a).

Further, the fuzzy rule strength release layer multiplies output values of input quantities of the first layer by two to obtain output values of the second layer, so that 25 nodes of the layer can be determined according to the output values of the first layer, and input and output expressions of the layer are as follows:

wherein, ω is_kRepresenting the activation strength of one of the fuzzy rules.

Further, the rule strength normalization layer calculates the proportion of the activation strength of each fuzzy rule, and the output expression is as follows:

further, the fuzzy rule output layer is used for calculating the output of each fuzzy rule, and the calculation expression is as follows:

wherein p is_k、q_kAnd r_kAs fuzzy nervesAnd obtaining the back-part parameters of the network through training.

Further, the output layer is used for calculating the output equalization current value I_eqThe calculation expression is as follows:

compared with the prior art, the invention has the following remarkable advantages:

the equalization control algorithm provided by the invention adopts the AUKF algorithm to improve the SOC estimation precision and solves the problem of possible overcharge and overdischarge damages to the battery when only the SOC is used as a parameter of the equalization control algorithm. And both the SOC and the terminal voltage are input into the adaptive fuzzy neural network. The self-adaptive fuzzy neural network combines the advantages of fuzzy logic control and the neural network, has strong self-adaptive capacity and high fault tolerance, and can adjust the membership function parameters and the weight between the neurons; the reasoning process is completed by the neuron, so that the speed is higher; the reliability of the algorithm can be improved by using expert experience. The fuzzy neural network designed by the invention is a first-order T-S fuzzy neural network, 5 parameters in total of a front part parameter and a back part parameter are required to be determined through learning, the learning algorithm adopts a hybrid algorithm of a BP algorithm and a least square method, the front part parameter is determined through the BP algorithm, and the back part parameter is determined through the least square method. And training the fuzzy neural network through data in the database, and identifying to obtain all parameters.

Drawings

FIG. 1 is a flow chart of an equalization control algorithm provided by the present invention;

FIG. 2 is a diagram of a second-order equivalent circuit model according to the present invention;

FIG. 3 is a SOC-OCV characteristic curve diagram of a lithium ion battery provided by the present invention;

FIG. 4 is a diagram of a low-high imbalance state according to the present invention;

FIG. 5 is a high-low imbalance state diagram according to the present invention;

fig. 6 is a diagram of a fuzzy neural network structure provided by the present invention.

Detailed Description

The technical solutions of the embodiments of the present invention are clearly and completely described below with reference to the drawings in the present invention, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, shall fall within the scope of protection of the present invention.

For ease of understanding and explanation, as shown in fig. 1-6, the present invention provides a battery energy equalization method suitable for an equalization circuit, comprising the steps of:

s1: collecting the voltage and current of the equalizing circuit;

s2: establishing a second-order equivalent circuit model, and estimating the SOC by using an AUKF algorithm;

s3: calculating the difference value of the SOC of different batteries, and judging whether the conditions of one low or one high or one low exist;

s4: establishing a neural network, and if the situation described in the step S3 exists, taking the terminal voltage as the input of the neural network, and determining whether the output equalization current value reaches an equalization threshold value;

s5: if the situation described in the step S3 does not exist, calculating an average value of the SOC of each battery, and determining whether the average value is between 0.2 and 0.8, and if so, determining whether the output equalization current value reaches an equalization threshold value by using the SOC as an input of the neural network; if the voltage is not between 0.2 and 0.8, the terminal voltage is used as the input of the neural network, and whether the output equalization current value reaches the equalization threshold value is judged;

s6: and when the output equalization current value reaches an equalization threshold value, the battery energy is equalized.

Example 1

The concentration polarization effect and the electrochemical polarization effect exist in the battery in the charging and discharging process, and the two effects can lead the terminal voltage and the SOC of the battery to present hysteresis loop. Therefore, the present application establishes a second-order RC equivalent circuit model, and the second-order RC equivalent circuit model in step S2 utilizes 2 RC networks to respectively address the concentration polarization effect and the electricityChemical polarization effects are described to improve model accuracy. The second order RC equivalent circuit model is shown in FIG. 2, U_OCV(t) is the open circuit voltage of the battery, and the two RC networks have four parameters in total, wherein R_e、C_eRespectively represents the electrochemical polarization internal resistance and the capacitance of the battery, R_d、C_dRespectively representing concentration polarization resistance and capacitance; r₀The ohmic internal resistance of the battery is shown, and I (t) shows the main circuit current, the discharging is positive, and the charging is negative.

From KCL and KVL laws, a circuit state expression can be derived as follows:

U_O(t)＝R_OI(t) (1)

wherein, U_O(t) is the ohmic voltage, U_e(t) electrochemical polarization voltage, U_d(t) is concentration polarization voltage;

U(t)＝U_OCV(t)+U_O(t)+U_e(t)+U_d(t) (4)

wherein U (t) is the battery terminal voltage;

obtaining an expression of the change of the SOC of the battery along with time by using a current integration method:

therein, SOC₀Is an initial SOC, Q_NThe standard capacitance of the battery is used, and eta is the charge-discharge efficiency of the battery;

discretization of formulae (2), (3) and (5) gives:

wherein, tau is a sampling period, tau_e＝R_eC_e，τ_d＝R_dC_d；

A discretized state space observation equation is established by equations (6), (7) and (8), as follows:

wherein w (k-1) is the observation noise of the model;

the discretized state output equation of the model is shown in equation (10):

U(k)＝U_OCV(k)+U_O(k)+U_e(k)+U_d(k)+v(k-1) (10)

where v (k-1) is the observation noise of the terminal voltage.

Example 2

The AUKF algorithm adopts an iterative updating method to estimate the system state, and in the iterative process, the maximum likelihood estimation and the expectation maximization method are used to continuously correct the system noise and the observation noise, so that the self-adaptive process is realized, and a better estimation effect is obtained. Based on the established battery equivalent circuit model, the AUKF algorithm in step S2 first constructs sampling points, and the state vector X (k) is composed of state variables SOC (k), U_e(k) And U_d(k) The composition is expressed as follows:

X(k)＝[SOC(k) U_e(k) U_d(k)]^T (11)

the step of estimating the SOC by using the AUKF algorithm in step S2 includes:

s21: initializing a nonlinear system:

s22: constructing 2n +1 sampling point sets and carrying out nonlinear conversion:

s23: the weight in the iterative calculation process is calculated as follows:

wherein the content of the first and second substances,

for a scale parameter, α represents the sampling point at

Distribution of the surroundings, i.e. 1>α>e^-4；

Generally takes on a value of

Beta is used to integrate X prior estimates, generally chosen to be 2; w_i ^(m)And W_i ^(c)Respectively calculating the weighted factors used for the mean value and the covariance of the ith sampling point;

s24: the one-step prediction for computing the 2n +1 sample point sets is:

Xⁱ(k-1)＝f(X_i,k-1),i＝0,1,…2n (16)

s25: the time update in the AUKF algorithm is:

s26: the measurements in the AUKF algorithm are updated as:

s27: the battery state variables and covariance are estimated as:

s28: adaptive law covariance matching:

where q (k) is the covariance of the model noise w (k), and r (k) is the covariance of the terminal voltage measurements v (k).

In the prior art, the SOC can accurately reflect the state of charge of the battery, and the performance of a control algorithm which selects the SOC as a unique distinguishing parameter can meet the actual requirement. However, when the battery is discharged in a low state, the voltage drop of the battery will increase rapidly, and when the battery is discharged with a large current, if the battery is not provided with the minimum voltage limiting protection, the battery will be in an overdischarge state for a long time, which may cause damage to the battery. Similarly, when the battery is discharged to a high state of charge, the voltage rise of the battery increases, and when the battery is charged with a large current, the battery is easily overcharged for a long time, and the battery is damaged. In addition, when the battery is severely aged, the polarization effect and the ohmic effect of the battery are more remarkable, and the voltage drop of the battery in a low-charge state and the voltage rise of a high-charge state are more obvious.

In summary, to prevent possible overcharge and overdischarge damage to the battery when only the SOC is used as a parameter of the equalization control algorithm. The invention adopts an equalization control algorithm based on SOC and terminal voltage, and uses the average value of SOC of the series battery pack as the basis of the equalization control algorithm of the terminal voltage or SOC. In combination with the SOC-OCV characteristic curve of the lithium ion battery determined in the figure 3, if the mean value of the SOC is between 0.2 and 0.8, an SOC-based equalization control algorithm is adopted; and if the mean value of the SOC is between 0 and 0.2 or 0.8 and 1, adopting a terminal voltage-based equalization control algorithm.

However, the SOC average value is not used as the only judgment basis of the selection algorithm in the invention in consideration of the unbalanced state diversity of the battery pack. When the charge amount of the battery pack is in a high-low unbalance state, as shown in fig. 4, although the SOC is equalized between 0.2 and 0.8, a high-charge-amount battery is close to a full charge state, and therefore, in order to avoid overcharging the high-charge-amount battery in the high-low unbalance state, it is necessary to employ a terminal-voltage-based equalization control algorithm. Similarly, when the battery pack is in an unbalanced state of low charge or high charge, as shown in fig. 5, in order to prevent the low-battery cell from over-discharging, an equalization control algorithm based on the terminal voltage is also required.

In summary, the specific flow of the equalization control adopted in the present invention is shown in fig. 1. In fig. 1, both SOC and terminal voltage are input to the adaptive fuzzy neural network. The self-adaptive fuzzy neural network combines the advantages of fuzzy logic control and the neural network, has strong self-adaptive capacity and high fault tolerance, and can adjust the membership function parameters and the weight between the neurons; the reasoning process is completed by the neuron, so that the speed is higher; the reliability of the algorithm can be improved by using expert experience.

Example 3

As shown in fig. 6, the neural network in step S4 includes: the fuzzy rule strength normalization layer comprises a fuzzy layer, a fuzzy rule strength release layer, a rule strength normalization layer, a fuzzy rule output layer and an output layer.

The input quantity of the blurring layer is 2, which are respectively the SOC difference value and the SOC average value, and can be expressed as:

therein, SOC_iThe SOC value, SOC, of the ith battery in the m single batteries on the left side of the equalizing unit_jThe SOC value of the jth battery in the n batteries at the right side of the equalizing unit is shown, delta SOC represents the difference value of the average values of the SOC at the left side and the right side of the equalizing unit, and SOC_avgRepresents the average value of the SOC on both sides of the equalizing unit;

defining the universe of the two input quantities according to the selected battery characteristics and respectively named A and B, wherein the universe of the two input quantities delta SOC of the SOC-based fuzzy neural network is [0,0.6 ]]，SOC_avgHas a discourse field of [0,1](ii) a Delta V in two input quantities of the fuzzy neural network based on terminal voltage is [0,1]，V_avgIs [2.6,4.2 ]](ii) a Considering the unbalanced state and the battery characteristics of the battery pack, dividing discourse domains of two input quantities into 5 fuzzy sets which are VS, S, M, L and VL respectively, and determining the membership function number of each input quantity; the membership function types are all Gaussian functions and are expressed as follows:

wherein a is the center of the membership function, b is the width of the membership function, and a and b are used as the front part parameters of the fuzzy neural network and are obtained by database training and learning;

input quantities delta SOC/delta V and SOC_avg/V_avgAre respectively defined as x₁And x₂: and obtaining an input and output expression of the first layer:

wherein, mu_Ai(x) Is an input quantity x₁Of the ith membership function, mu_Bj(x) Is a number x₂The jth membership function of (a).

(II) the fuzzy rule strength release layer multiplies output values of input quantities of the first layer by two to obtain output values of the second layer, so that 25 nodes of the layer can be determined according to the output values of the first layer, and input and output expressions of the layer are as follows:

wherein, ω is_kRepresenting the activation strength of one of the fuzzy rules.

(III) the rule strength normalization layer calculates the proportion of the activation strength of each fuzzy rule, and the output expression is as follows:

and (IV) the fuzzy rule output layer is used for calculating the output of each fuzzy rule, and the calculation expression is as follows:

wherein p is_k、q_kAnd r_kThe parameters are acquired through training as the back-piece parameters of the fuzzy neural network.

Fifthly, the output layer is used for calculating the output equilibrium current value I_eqThe calculation expression is as follows:

the above disclosure is only for a few specific embodiments of the present invention, however, the present invention is not limited to the above embodiments, and any variations that can be made by those skilled in the art are intended to fall within the scope of the present invention.

Claims (10)

1. A battery energy balancing method suitable for a balancing circuit is characterized by comprising the following steps:

s1: collecting the voltage and current of the equalizing circuit;

s2: establishing a second-order equivalent circuit model, and estimating the SOC by using an AUKF algorithm;

s3: calculating the difference value of the SOC of different batteries, and judging whether the conditions of one low or one high or one low exist;

s4: establishing a neural network, and if the situation described in the step S3 exists, taking the terminal voltage as the input of the neural network, and determining whether the output equalization current value reaches an equalization threshold value;

s5: if the situation described in the step S3 does not exist, calculating an average value of the SOC of each battery, and determining whether the average value is between 0.2 and 0.8, and if so, determining whether the output equalization current value reaches an equalization threshold value by using the SOC as an input of the neural network; if the voltage is not between 0.2 and 0.8, the terminal voltage is used as the input of the neural network, and whether the output equalization current value reaches the equalization threshold value is judged;

s6: and when the output equalization current value reaches an equalization threshold value, the battery energy is equalized.

2. The battery energy equalization method for equalization circuits as claimed in claim 1, wherein the second-order equivalent circuit model in step S2 describes the concentration polarization effect and the electrochemical polarization effect by using 2 RC networks, respectively, and according to KCL and KVL laws, a circuit state expression can be obtained as follows:

U_O(t)＝R_OI(t) (1)

wherein, U_O(t) is the ohmic voltage, U_e(t) electrochemical polarization voltage, U_d(t) is concentration polarization voltage;

U(t)＝U_OCV(t)+U_O(t)+U_e(t)+U_d(t) (4)

wherein U (t) is the battery terminal voltage;

obtaining an expression of the change of the SOC of the battery along with time by using a current integration method:

therein, SOC₀Is an initial SOC, Q_NThe standard capacitance of the battery is used, and eta is the charge-discharge efficiency of the battery;

discretization of formulae (2), (3) and (5) gives:

wherein, tau is a sampling period, tau_e＝R_eC_e，τ_d＝R_dC_d；

A discretized state space observation equation is established by equations (6), (7) and (8), as follows:

wherein w (k-1) is the observation noise of the model;

the discretized state output equation of the model is shown in equation (10):

U(k)＝U_OCV(k)+U_O(k)+U_e(k)+U_d(k)+v(k-1) (10)

where v (k-1) is the observation noise of the terminal voltage.

3. The battery energy balancing method suitable for the balancing circuit as claimed in claim 2, wherein the AUKF algorithm in step S2 first constructs sampling points, and the state vector X (k) is composed of the state variables SOC (k), U_e(k) And U_d(k) The composition is expressed as follows:

X(k)＝[SOC(k) U_e(k) U_d(k)]^T (11) 。

4. the battery energy balancing method applicable to the balancing circuit according to claim 3, wherein the step of estimating the SOC by using the AUKF algorithm in step S2 comprises:

s21: initializing a nonlinear system:

s22: constructing 2n +1 sampling point sets and carrying out nonlinear conversion:

s23: the weight in the iterative calculation process is calculated as follows:

wherein the content of the first and second substances,

for a scale parameter, α represents the sampling point at

Distribution of the surroundings, i.e. 1>α>e^-4；

Generally takes on a value of

Beta is used to integrate X prior estimates, generally chosen to be 2;

and

respectively calculating the weighted factors used for the mean value and the covariance of the ith sampling point;

s24: the one-step prediction for computing the 2n +1 sample point sets is:

Xⁱ(k-1)＝f(X_i,k-1),i＝0,1,…2n (16)

s25: the time update in the AUKF algorithm is:

s26: the measurements in the AUKF algorithm are updated as:

s27: the battery state variables and covariance are estimated as:

s28: adaptive law covariance matching:

where q (k) is the covariance of the model noise w (k), and r (k) is the covariance of the terminal voltage measurements v (k).

5. The battery energy balancing method for the balancing circuit according to claim 1, wherein the neural network in step S4 includes: the fuzzy rule strength normalization layer comprises a fuzzy layer, a fuzzy rule strength release layer, a rule strength normalization layer, a fuzzy rule output layer and an output layer.

6. The battery energy balancing method for the balancing circuit according to claim 5, wherein the input amount of the blurring layer is 2, which are the SOC difference value and the SOC average value, and can be expressed as:

therein, SOC_iThe SOC value, SOC, of the ith battery in the m single batteries on the left side of the equalizing unit_jThe SOC value of the jth battery in the n batteries at the right side of the equalizing unit is shown, delta SOC represents the difference value of the average values of the SOC at the left side and the right side of the equalizing unit, and SOC_avgRepresentation equalizationThe average of the SOC across the cell;

defining the universe of the two input quantities according to the selected battery characteristics and respectively named A and B, wherein the universe of the two input quantities delta SOC of the SOC-based fuzzy neural network is [0,0.6 ]]，SOC_avgHas a discourse field of [0,1](ii) a Delta V in two input quantities of the fuzzy neural network based on terminal voltage is [0,1]，V_avgIs [2.6,4.2 ]](ii) a Considering the unbalanced state and the battery characteristics of the battery pack, dividing discourse domains of two input quantities into 5 fuzzy sets which are VS, S, M, L and VL respectively, and determining the membership function number of each input quantity; the membership function types are all Gaussian functions and are expressed as follows:

wherein a is the center of the membership function, b is the width of the membership function, and a and b are used as the front part parameters of the fuzzy neural network and are obtained by database training and learning;

input quantities delta SOC/delta V and SOC_avg/V_avgAre respectively defined as x₁And x₂: and obtaining an input and output expression of the first layer:

wherein the content of the first and second substances,

is an input quantity x₁The ith membership function of (a),

is a number x₂The jth membership function of (a).

7. The battery energy balancing method for the balancing circuit as claimed in claim 5, wherein the fuzzy rule strength releasing layer multiplies the output values of the input quantities of the first layer by two to obtain the output values of the second layer, so that 25 nodes of the layer can be determined from the output values of the first layer, and the input and output expressions of the layer are:

wherein, ω is_kRepresenting the activation strength of one of the fuzzy rules.

8. The battery energy balancing method for the balancing circuit as claimed in claim 5, wherein the rule strength normalization layer calculates the proportion of the activation strength of each fuzzy rule, and the output expression is:

9. the battery energy equalization method for an equalization circuit according to claim 5, wherein the fuzzy rule output layer is configured to calculate an output of each fuzzy rule, and the calculation expression is as follows:

wherein p is_k、q_kAnd r_kThe parameters are acquired through training as the back-piece parameters of the fuzzy neural network.

10. The battery energy equalization method for equalization circuit as claimed in claim 5, wherein said output layerEqualizing current value I for calculating output_eqThe calculation expression is as follows:

。

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