Li-ion Battery Aging Conscious Intelligent Energy

Management Strategy for Hybrid Electric Buses

Estrategia inteligente basada en envejecimiento de la bater

ıa

de litio-ion para la gesti

on energ

etica de autobuses h

ıbridos

ectricos

Abstract— This paper aims to propose a battery aging

conscious energy management strategy. The initial design

of an energy management strategy is a signiﬁcant point

to fulﬁll the efﬁciency goals in the short term. However,

with aging, the initial conditions may vary. The new

trend of digitalization allows monitoring the operation,

having the possibility to improve the performance of the

initially proposed strategy in the long term. Therefore, a

methodology for updating the energy management strategy

along the bus lifetime is intended to improve the operating

costs and extend the battery lifetime. This methodology is

based on a dynamic programming optimization, tuning

the membership functions in a fuzzy logic control. The

simulation results show a reduction of the operation costs

up to 47% as long as it stands for battery (BT) lifetime

extension of around 2.94%.

Keywords— Energy management, dynamic program-

ming, fuzzy logic, hybrid electric bus, state of health,

energy storage systems.

Resumen— El objetivo de este trabajo es proponer

una estrategia inteligente basada en el envejecimiento

de la bater

ıa de litio-ion instalada abordo de veh

ıculo

como aplicaci

on de gesti

on energ

etica. El dise

no inicial

de una estrategia de gesti

on energ

etica (EMS) es un

paso signiﬁcativo para cumplir los objetivos de eﬁciencia

en la operaci

on a corto plazo. Sin embargo, debido al

envejecimiento de la bater

ıa las condiciones iniciales de

la EMS pueden variar. La nueva tendencia hacia la

digitalizaci

on permite monitorizar la operaci

on, brindando

la posiblidad de mejorar el desempe

no de la estrategia

inicialmente propuesta en el largo plazo. Por lo tanto, se

propone una metodolog

ıa para actualizar la EMS con el

objetivo de mejorar los costos de operaci

on y extender

la vida

util de la bater

ıa. La metodolog

ıa se basa en una

optimizaci

on mediante programaci

on din

amica para para-

metrizar las funciones de pertenencia de un control difuso.

Los resultados de simulaci

on muestran una reducci

on en

los costos de operaci

on entorno al 47 % junto con una

extensi

on de la vida

util de la bater

ıa de alrededor de

2.94 %.

Palabras Clave— Gesti

on energ

etica, programaci

din

amica, l

ogica difusa, autob

us h

ıbrido el

ectrico, estado

de salud, sistema de almacenamiento de energ

ıa.

I. INTRODUCTION

Nowadays, urban transport is undergoing a funda-

mental shift to greener and more sustainable solutions.

This evolution has been driven by two main factors, a

growing awareness of the emitted pollution, especially

in urban areas and the lithium-based batteries (BTs)

price decrease (nearly 79% since 2010 [1]). However,

the implementation of hybrid and electric buses is a

challenging process due to the high investment cost

besides conventional buses.

Some studies pointed out the inﬂuence of the BT price

on the buses total cost, reaching values of the 39% [2].

Adding the fact that BTs have a shorter lifetime than

power electronic systems, the BT system is identiﬁed as

a bottleneck in the lifetime of the bus. Moreover, that BT

pack replacements are required, this affects signiﬁcantly

to the operation costs during the vehicle lifetime [3], [4],

increasing the total cost of ownership (TCO). Therefore,

it can be said that the BT lifetime is closely related to

vehicle operation.

Jon Ander López-Ibarra

1,3,♦

, Mattin Lucu

1,3

, Nerea Goitia-Zabaleta

, Haizea Gaztañaga

, Victor Isaac

Herrera

2,♣

, Haritza Camblong

3,4,♠

IKERLAN Technology Research Centre Energy Storage and Management Area Gipuzkoa, Spain

Escuela Superior Politécnica de Chimborazo, Facultad de Informática y Electrónica, Riobamba, Ecuador

Email:

♦

jonander.lopez@ikerlan.es,

♣

isaac.herrera@espoch.edu.ec,

♠

aritza.camblong@ehu.eus

University of the Basque Country Gipuzkoa, Spain

ESTIA Research, France

Fecha de Recepción: 16 – May – 2019 Fecha de Aceptación: 13 – Jun – 2019

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For bus manufacturers, the developed initial energy

management strategy (EMS) for fulﬁlling the efﬁciency

operation goals is a signiﬁcant point. However, the

conditions used for the initial EMS vary throughout

the bus lifetime. Therefore, an update of the initial

EMS will adjust the EMS to the new situation. For the

correct update of the EMS, the continuous operation

monitoring is needed. This need is fulﬁlled with the latest

vehicles digitalization trend, which allows the constant

monitoring of the operation. Consequently, having the

possibility to analyze the current operation and take

action to correct it.

The operation information with the needed BT ad-

vance knowledge will allow managing the BT lifetime,

going a step further on the EMS. In this regard, new

techniques for managing the BT aging are needed, since

BT replacements are directly related to the TCO. Con-

sequently, the operation management conscious of the

BT aging will allow improving the TCO further. As a

result, they are making urban mobility electriﬁcation a

more attractive and viable solution for investors.

Dealing with hybrid propulsion systems, several EMSs

have been proposed in the literature with a multi-

objective strategy to minimize fuel consumption and at

the same time minimize the capacity loss and extend the

BT lifetime [5], [6]. It has been underlined that these

strategies do not consider the state of health (SOH) of

the BT as an input. The SOH is a piece of valuable

information, which enables the maximization of the BT

lifetime in a long-term scope.

The SOH enables to act to manage the BT lifetime in

a long term scope. In [4], Du J. et. al propose an EMS

for an hybrid electric bus (HEB) with a hybrid energy

storage system (HESS), to minimize the BT degradation

and total costs. However, this minimization process is

based on the power management of the HESS, without

any updates of the EMS within the bus lifetime.

This paper aims to develop a BT aging conscious

intelligent EMS focused on imporving the BT lifetime.

In the ﬁrst part, a fuzzy logic (FL) algorithm is devel-

oped based on the short term EMS initially designed.

This strategy is tuned by using the optimal operation

obtained by dynamic programming (DP) optimization.

This strategy is tuned based on the optimal operation

obtained by dynamic programming (DP) optimization.

As the initial conditions vary and the BT capacity fades,

a methodology for updating the EMS is proposed, to

maximize the BT aging and improve the operating costs.

Operation costs improvements up to 47% are obtained

beside a rule-based strategy, and a BT lifetime extension

of 2.94% is reached.

II. S

CENARIO OVERVIEW

The scenario analyzed in this paper is based on a

series hybrid electric bus (SHEB) that performs in an

urban route. As shown in Fig. 1, this type of bus

power-train is pulled by an electric motor (EM). In this

conﬁguration, the required power is provided by a genset

(GS, composed by an internal combustion engine (ICE)

coupled to an electric generator) and a BT pack.

The parameters of this scenario are listed in Table I

[7].

Simulation in MATLAB has been performed. For this

simulation, line 28 from Donostia-San Sebastian (Spain)

urban bus route has been used. It is worth to highlight

that the BT used in this SHEB is fast charged after every

round-trip, except for the last round-trip, which is depot

charged. The driving proﬁle is depicted in Fig 2.

III. B

ATTERY AGING CONSCIOUS INTELLIGENT

ENERGY MANAGEMENT STRATEGY

The suitable and efﬁcient power split among the GS

and BT became a complex problem. There are several

factors to take into account to minimize fuel consump-

tion. Furthermore, if BT aging management is included

in the problem, it becomes even more complex. To an-

swer this problem, advanced techniques and knowledge

of the BT and application are needed, as a fair trade

between the fuel consumption minimization and the BT

utilization management has to be determined.

In this context, FL rule-based EMS has been consid-

ered as the technique to deal with the complex problem.

The main reason for using FL has been the capacity of

this technique to adapt to the uneven events during the

real operation, due to the non-linear variable response

depending on the operation conditions [7].

Therefore, a FL based BT conscious EMS has been

proposed. In the following subsections the proposed

EMS FL membership functions, optimization used for

Electric

Generator

Gen-Set

Electric

Motor

DC Bus

Battery

Mechanical Link

DC Link

AC Link

Clutch

ICE

Figure 1: Series HEB conﬁguration.

Table I: Scenario approach.

Elements Units Parameters

Electric Motor Power kW 196.5

Genset Power kW 160

Battery Pack

Voltage V 650

Energy kWh 24

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the tuning and the output are described. In Fig. 3 an

overview of the proposed FL EMS is shown.

A. Fuzzy Logic Membership functions

The proposed FL controller have been based on a

Sugeno Fuzzy Inference System [8], due to the less pro-

cessing needed time. The utilized membership functions

are detailed in Fig. 4. The names of the membership

functions have been deﬁned as follows:

- GS power (

(k − 1) [W ]): the input data is the

previous GS power value, to avoid sudden GS power

demands.

- Regeneration capability (

Regen

[W ]): the input data

is the difference between the maximum BT charging

power and the regenerated power in the continuous bus,

to maximize the BT regenerative charging.

- DC link power balance (

DCLink

[W ]): the input stands

for the power balance of the continuous bus, to evaluate

the power demand

- BT State of Charge (

SOC): the input is the current

SOC of the BT, to evaluate if the BT needs to be charged

or discharged.

B. Fuzzy Logic Tuning

The tuning of the proposed EMS has been based

on both advance application knowledge and an off-line

optimization of the driving proﬁle. The DC link power

balance [W], GS Power [W], and Regeneration capability

[W] membership functions have been tuned based on

the advanced application knowledge. On the contrary,

the SOC [%] has been adjusted based on the optimal

operation obtained from DP optimization.

The predeﬁned driving proﬁle has been optimized

based on DP optimization. The optimization problem is

based on the following cost function (

J), for the fuel

consumption minimization [9]:

J =

N−1



i=0

m

(U(i)) · T

(1)

where

m

· T

is the fuel mass consumption at each

time step (

=1 s), determined by the split factor (U),

within the urban route length (N) [10]. Therefore the

optimized parameter is the split factor.

In the SHEB conﬁguration, the split factor stands for

the division of the power demand (

dem

[W ]) among the

GS (

[W ]) and the ESS (P

ESS

[W ]).

dem

(i)=



(i)=P

dem

(i) · (1 − U(i))

(i)=P

dem

(i) · U(i)

(2)

To maximize the BT use obtaining the lowest fuel

consumption, the optimization has been designed, to

reach a predeﬁned minimum SOC. This minimum SOC

has been calculated based on the amount of energy that

can be recharged with the available fast charger power

in 2.5 minutes.

From the obtained optimal SOC operation, the min-

imum and maximum SOC values are extracted. These

points are used to set the A (minimum SOC) and B

(maximum SOC) points, as shown in Fig. 4.

C. Fuzzy Logic Output

The output variable of the proposed EMS is the GS

power [W]. In Sugeno Fuzzy Inference System, the

output values are defuzziﬁed by statistic functions [11].

The output statistics function used in this design is the

weighted arithmetic mean value. Each data point has a

degree of contribution, also denominated as weight, on

the weighted arithmetic mean calculus. Consequently,

for calculating the output, weighted values are required.

These weighted values are computed by another mathe-

matical function denominated as the propagation of error,

Eq. (3). In this case, the weight refers to the contribution

of the FL controller rules (

r ule

) for each GS power

value,

GSvalue



rule

+ w

rule

+ ... + w

rule

(3)

. . .

Operation [hours]

Back

Fast Charging Zone

Speed Profile

Depot Charging Zone

Back

. . .

Speed [km/h]

Figure 2: Driving proﬁle.

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After obtaining the weighted value, weighted arith-

metic means statistics function can be applied to obtain

GS (

output

) output value. The following formula is

used for the output deﬁnition:

output



i=1

GSi

· GS

)



i=1

GSi

(4)

where,

[W ] are the GS constants, deﬁned by n the

number of constants and

GSi

represents the weighted

value of each constant.

is tuned based on the obtained DP optimal GS

operation values. This tuning is based on extracting the

minimum, quantiles 25, 50 and 75, and the maximum

values.

IV. EMS U

PDATING METHODOLOGY

The complexity of the energy management problem

increases as the conditions used for the initial EMS

design conditions vary. This initial EMS is a signiﬁcant

point for fulﬁlling the operation and efﬁciency goals.

However, the state of the bus with the aging differs,

identifying the BT as a bottleneck in the lifetime of

the bus. For this reason, BT conscious EMS has been

proposed.

The BT aging analysis and estimation is also a

complex task as it has been aforementioned in Sec. I.

This is the main reason for the need of updating the

initial EMS. For the correct update of the EMS, the

continuous operation monitoring is needed. This will

allow to analyze the current operation and take action

to correct it.

Therefore, a methodology for updating the EMS to

correct the SOH of the BT, fulﬁlling the operation

conditions is presented. The proposed methodology is

shown in Fig. 5. For the initial and subsequent EMS

Fuzzification

μP_GS [-]

SOC [%]

DC_link

P [W]

Regen

Rules

Inference

Defuzzification

μP_DC_link [-]

μP_Regen [-]

μSOC [-]

P (k-1) [W]

Tuning-Update

P [W]

GSvalue

w [-]

[W]

DP based optimisation

Figure 3: Fuzzy Logic control block diagram.

-1.5

-1

-0.5 0 0.5

x10

1.5

DC Link Power Balance [W]

SOC [%]

100

0.5

Deg. of Membership

Negative

Null

Low

Medium

High

Very Low

Low

Medium

High

0.5

x10

Genset Power [W]

Very Low

Low

Medium

High

Very High

0.5

x10

Very Low

Low

Medium

Regeneration capability [W]

μP_GS [-]

Deg. of MembershipDeg. of MembershipDeg. of Membership

μP_Regen [-]

μSOC [-]

μP_DC_link [-]

Figure 4: Fuzzy Logic membership functions.

designs, two periods have been set, the short and the

long terms subsequently. In the following lines, the

methodology stages are presented in detail.

Stage 1: Driving Proﬁle Operation Optimization

In the ﬁrst stage, the Short Term EMS design is

developed. Thes initial EMS has been designed for

fulﬁlling the operation efﬁciency goals.

Stage 2: Urban bus operation

In this stage, a simulation in MATLAB of the urban

bus real operation driving behavior (described in Sec. II)

is performed. For the real driving operation conditions,

driving disruptions have been considered, such as passen-

ger, auxiliary and trafﬁc disruptions [10]. Additionally,

in this simulation, continuous operations monitoring is

done during 15 days.

Stage 3: Analysis and Decision Maker

This stage consists of analyzing the current aging of

the BT and updating the EMS, to improve the operation

from the initial EMS design. The continuous operation

data gathered in the urban bus operation simulation is

processed, and the BT aging is obtained and analyzed.

Subsequently, to adapt the new EMS to the new condi-

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Figure 5: EMS updating methodology.

tions, decisions are made. For that purpose, the following

three stages are required:

Stage 3.1: Battery Aging Analysis

For a correct BT aging management, apart from ad-

vanced BT knowledge, an appropriate BT aging model

is needed. BT lifetime estimation is a complex task due

to the dependence on multiple stress factors [12]. The

literature proposes different aging models, which can

be categorized as physiochemical, empirical or semi-

empirical with uneven levels of complexity and accuracy

[12], [13]. The semi-empirical model is the most widely

used method [12]. For this work, a W

ohler curve based

fatigue method has been used.

Firstly, both estimated and real aging curves are com-

pared in a determined evaluation period. This evaluation

period has been set of steps of 5% of the SOH decrease

(

SOH) until the end-of-life (EOL) of the BT is

reached. In other words, BT aging is evaluated in

95%, P

90%, P

85% and P

80% of SOH. The real

aging estimation (blue curve), reaches a lifetime of



Consequently, the aging curve varies from the initially

estimated one. In this evaluation points, to extend the BT

lifetime, there is a need for updating the EMS, to reach



Stage 3.2: Long Term Design

To improve the operation obtained from the initial

EMS, to determine the most convenient operation. This

stage has been divided into two, the driving proﬁle re-

optimization and the techno-economic evaluation.

Driving Proﬁle Re-optimization

These re-optimizations consist of modifying the re-

quested charging power from 50 kW to 150 kW by a step

of 10 kW. In this way, as the EMS is designed based on

the available energy to be recharged (explained in Sec.

III-B), the BT utilization will be reduced as the charging

power decreases. Consequently, the strategy will increase

the GS, improving the BT lifetime. On the contrary, if

the BT aging is considered to be as designed, the BT

utilization is increased, re-tuning the SOC membership

function.

Techno-Economic Evaluation

At this point, the obtained optimization results are

techno-economically analyzed. In this outline, the fol-

lowing operating costs are taken into account: fuel con-

sumption cost, BT cost, and BT charging energy cost,

Eqs. (5), (6) and (6), respectively.

cost



k=1

(mf

ICE

(k) · k

· C

L,fuel

)

fuel

[e/day] (5)

where

fuel

is the fuel volumetric density [kg/l], k

the global factor to cold starts [-] and

L,fuel

[e/l] is

fuel, in this case diesel, cost per liter.

cost

· E

· n

L · O

deg

deg,current

[e/day] (6)

where

is the BT cost in [e/kWh], E

is the BT

size [kWh], n are the number of replacements,

L is the

lifetime operation of the BT [years],

O is the yearly

operation in [day/years],

deg

are the predicted years and

deg,current

are the current years.



= C

e,fix

+ C

e,var

[e/day]

(7)

where

el,f ix

is the ﬁx power cost in [e/day] and C

e,var

is the consumed energy cost in [e/day]. Both costs are

calculated as follows:



el,f ix

= C

· P

cha

[e/day]

(8)



el,var

= C

kW h

· E

cha

[e/day]

(9)

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where, C

represents the cost of the charging power,

cha

the charging infrastructure power, C

kW h

the energy

cost and

cha

the consumed energy from the grid.

The objective of this analysis is to reduce fuel con-

sumption and extend BT lifetime. According to the devi-

ation of the SOH and the techno-economical boundaries,

an optimization is selected.

Stage 3.3: Decision Maker

In this sub-stage, based on the obtained results form

the re-optimization and techno-economic analysis, the

most suitable operation will be determined for the long

term EMS design. For this, a fuel consumption limit

has been established, which limits the obtained opti-

mizations results. Therefore, based on the performed

techno-economical analysis, the most suitable operation,

according to the BT aging, is chosen.

Stage 4 EMS update

In this Long Term EMS, the selected SOH optimization

via DP is used for tuning off-line FL strategy, until

the next evaluation period. In the same way as short

term EMS, SOC input, and GS output are the adjusted

variables. In this EMS operation targets are modiﬁed, to

correct the BT degradation, obtaining the re-evaluated

BT aging curve (green curve, Fig 5). The re-evaluated

BT aging maximizes the BT lifetime until point A”.

After this design, the EMS is updated to Long Term

EMS, and the operation is simulated in MATLAB until

the next evaluation period.

V. R

ESULTS AND ANALYSIS

To validate the proposed BT conscious EMS and EMS

updating methodology, a simulation of the presented

SHEB in Section II has been carried out.

In this section, the obtained results are presented. First,

the proposed EMS evaluation has been performed. Then,

the obtained results from the short and long terms are

presented.

A. Proposed EMS evaluation

In Fig. 6 the proposed EMS comparison is shown. The

proposed EMS has been ﬁrst compared against a DP

off-line optimization and with the proposed rule-based

non-adaptive EMS named LUT (Look up table based

EMS) [10]. The operation costs of the proposed approach

increase compared to the DP global optimization which

has a value of 31.5%. Another comparison is done

against the LUT strategy obtaining an increase of 63.7%.

Additionally, the obtained operation costs improvement

of the proposed EMS compared to the LUT EMS is up to

47%. Indeed, to ensure the adaptability of the proposed

approach, a comparison with the maximum demand of

auxiliaries and number of passengers on the bus, against

High Price

Scenario

Low Price

Scenario

- 63.7%

- 47.0%

- 44.3%

- 31.5%

+ 5.1%

- 21.2%

Figure 6: EMS comparison.

the LUT EMS has been done resulting on a decrease of

44.3% of operating costs for the proposed EMS.

For further evaluation and to ensure the stability of

the proposed EMS, the worst and best cases have been

assessed. The obtained result in the best case, i.e. the bus

without passengers and with the minimum of auxiliary

consumption, has been a decrease of 21.2%. On the

contrary, the worst case has been the evaluation with

the maximum of passengers and maximum auxiliary

consumption, obtaining an increase of 5.1%.

B. Short and long term evaluations

In this subsection, the proposed methodology for up-

dating the EMS has been analyzed. For this comparison,

the non-updated EMS has been deﬁned as the short term

ST, and the updated one as the long term LT.

In Fig. 7 the obtained results regarding the BT aging

are shown. The BT aging extension for the updated EMS

2.94% against the non-updated EMS. It is noteworthy the

BT aging lifetime of the ST, as it does not fulﬁll the vehi-

cle end-of-life (EOL) planned years. On the contrary, the

updated LT EMS overcomes the expected vehicle EOL

point. Concerning the BT aging deviation concerning the

vehicle lifespan, two scenarios are analyzed. In a ﬁrst

analysis, a unique BT replacement is considered in the

whole vehicle life, and the vehicle not reaching EOL is

removed before the planned date. The second case study,

100

SOH [%]

0 0.2 0.4 0.6 0.8

Battery aging [pu]

Updated strategy

Non-updated

Evaluation points

Vehicle end-of-

life

strategy

0.97

Figure 7: Corrected BT aging.

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Operation Costs [€/day]

4 eval

3 eval

2 eval

1 eval

Evaluation Periods

2.5% 1.3% 0.5%

Figure 8: ST and LT comparison with a single replace-

ment.

Operation Costs [€/day]

4 eval

3 eval

2 eval

1 eval

Evaluation Periods

3.0% 4.8% 4.1%

Figure 9: ST and LT comparison with two replacements

for the bus not reaching the vehicle EOL point, a second

BT replacement has been considered.

Fig. 8 shows the operation costs obtained on each

evaluation point for each EMS, the ST, and the LT. The

ST EMS shows lower operation costs than LT EMS,

reaching values up to 2.5%.

By contrast, as shown in Fig. 9, if the vehicle requires

two BT replacements, the opposite happens. A decrease

up to 4.8% in the LT EMS is obtained in the operation

costs.

VI. C

ONCLUSIONS

In this paper, a BT aging conscious intelligent energy

management strategy was presented focused on BT life-

time maximization. For the validation of the proposed

BT conscious EMS and EMS update methodology, a

simulation as described in Section II is carried out.

The obtained results against a non-adaptive EMS has

been up to 47% of operation costs decrease. For the

stability evaluation, the worst and best cases have been

evaluated, obtaining an increase of the operation costs

up to 5.1% and a decrease up to 21.2% respectively.

The BT aging extension has been of 2.94%, compared

to the non-updated EMS, reaching the planned bus

EOL. However, in the case of the non-updated EMS,

the scheduled EOL date is not reached. In this regard,

the two analyzed possibilities are to remove the bus

before the planned time or to replace the BT. In the

case of removing the bus, the obtained results for the

ST operating cost have a decrease up to 2.5%. On the

contrary, considering to replace the BT, the operation

costs of the LT EMS decrease up to a 4.8%, since the

BT lifetime overcomes the planned EOL date and an

only BT replacement is needed. It is worth to highlight

that the penalization for not reaching the bus EOL was

not taken into account for the scenario of removing the

bus.

On the ongoing research, an improved and self-

adaptive [14] BT aging estimation model will be im-

plemented to the BT aging conscious EMS.

CKNOWLEDGMENT

This work was partially supported by the Gipuzkoa

Provincial Council under Project On-Mobility (Regional

Program Red Guipuzcoana de Ciencia, Technology and

Innovation).

EFERENCES

[1] The latest bull case for electric cars: the cheapest batteries ever.

Available:https://www.bloomberg.com/news /articles/2017-12-

05/latest-bull-case-forelectric- cars-the-cheapest-batteries-ever,

05-12-2017 [Accessed: 26-04-2018].

[2] Z. Bi, L. Song, R. De Kleine, C. C. Mi, and G. A.

Keoleian, “Plug-in vs. wireless charging: Life cycle energy and

greenhouse gas emissions for an electric bus system,” Applied

Energy, vol. 146, no. February, pp. 11–19, 2015. [Online].

Available: http://dx.doi.org/10.1016/j.apenergy.2015.02.031

[3] R. Dufo-L

opez, “Optimisation of size and control of grid-

connected storage under real time electricity pricing condi-

tions,” Applied Energy, vol. 140, pp. 395 – 408, 2015.

[4] J. Du, X. Zhang, T. Wang, Z. Song, X. Yang,

H. Wang, M. Ouyang, and X. Wu, “Battery degradation

minimization oriented energy management strategy for plug-

in hybrid electric bus with multi-energy storage system,”

Energy, vol. 165, pp. 153–163, 2018. [Online]. Available:

https://doi.org/10.1016/j.energy.2018.09.084

[5] L. Tang, G. Rizzoni, and S. Onori, “Energy management

strategy for HEVs including battery life optimization,” IEEE

Transactions on Transportation Electriﬁcation, vol. 1, no. 3,

pp. 211–222, 2015.

[6] L. Tang and G. Rizzoni, “Energy management strategy in-

cluding battery life optimization for a HEV with a CVT,”

2016 IEEE Transportation Electriﬁcation Conference and Expo,

Asia-Paciﬁc, ITEC Asia-Paciﬁc 2016, pp. 549–554, 2016.

[7] V. I. Herrera, A. Milo, H. Gazta

naga, J. Ramos, and H. Camb-

long, “Adaptive and non-adaptive strategies for optimal energy

management and sizing of a dual storage system in a hybrid

electric bus,” IEEE Transactions on Intelligent Transportation

Systems, pp. 1–13, 2018.

Revista Técnico - Cientíca PERSPECTIVAS

Volumen 1, Número 2. (Julio - Dicimbre 2019)

e -ISSN: 2661-6688

[8] T. Takagi and M. Sugeno, “Fuzzy Identiﬁcation of Systems and

Its Applications to Modeling and Control,” IEEE Transactions

on Systems, Man, and Cybernetics, vol. SMC-15, no. 1, pp.

116–132, 1985.

[9] O. Sundstr

om and L. Guzzella, “A Generic Dynamic Program-

ming Matlab Function,” 18th IEEE International Conference

on Control Applications, Saint Petersburg, Russia, no. 7, pp.

1625–1630, 2009.

[10] J. A. Lopez, V. I. Herrera, A. Milo, and H. Gazta

naga,

“Energy Management improvement based on Fleet

Learning for Hybrid Electric Buses,” in IEEE Vehicle

Power and Propulsion Conference (VPPC). Chicago, IL,

USA, USA: IEEE, 2018, pp. 2–7. [Online]. Available:

https://ieeexplore.ieee.org/document/8605025

[11] Mathworks. Sugeno fuzzy interference system. Available:

https://es.mathworks.com/help/fuzzy/sugﬁs.html [Accessed: 05-

12-2018].

[12] M. Dubarry, N. Qin, and P. Brooker, “Calendar aging

of commercial Li-ion cells of different chemistries

– A review,” Current Opinion in Electrochemistry,

vol. 9, pp. 106–113, 2018. [Online]. Available:

https://doi.org/10.1016/j.coelec.2018.05.023

[13] D. U. Sauer and H. Wenzl, “Comparison of different approaches

for lifetime prediction of electrochemical systems-Using lead-

acid batteries as example,” Journal of Power Sources, vol. 176,

no. 2, pp. 534–546, 2008.

[14] M. Lucu, E. Martinez-Laserna, I. Gandiaga, and

H. Camblong, “A critical review on self-adaptive li-ion

battery ageing models,” Journal of Power Sources,

vol. 401, pp. 85 – 101, 2018. [Online]. Available:

http://www.sciencedirect.com/science/article/pii/S0378775318

309297

Revista Técnico - Cientíca PERSPECTIVAS

Volumen 1, Número 2. (Julio - Dicimbre 2019)

e -ISSN: 2661-6688