467.600 PEOPLE
| People | Locations | Statistics |
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| Serhiienko, Serhii |
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| Schmalz, Ulrike |
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| Oliveira, Marisa |
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| Ribeiro Pereira, Maria Teresa |
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| Bellér, Gábor |
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| Araujo, M. |
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| Frey, Michael | Karlsruhe |
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| Coutinho-Rodrigues, João | Coimbra |
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| Wouters, Christian Guillaume Louise | Aachen |
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| Kessel, Paul J. Van Van |
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| Árpád, István |
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| Fontul, Simona |
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| Kocsis, Dénes |
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| Cigada, Alfredo | Milan |
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| Oort, Neils Van | Delft |
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| Agárdi, Anita | Miskolc |
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| Andrews, Gordon E. |
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| Sousa, Nuno |
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| Witlox, Frank Jacomina Albert | Ghent |
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| Dobruszkes, Frederic |
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| Kiss, Judit T. |
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| Hadachi, Amnir | Saint-Étienne-du-Rouvray |
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| Hamilton, Carl J. | Kunovice |
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| Misiura, Serhii |
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| Schimpf, Marina |
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Ansean, David
University of Oviedo
in Cooperation with on an Cooperation-Score of 37%
Topics
- accumulator
- learning
- submarine
- nickel
- ion
- lithium
- battery charging time
- graphite
- silicon
- supervision
- deterioration
- monitoring
- health
- assessment
- neural network
- diagnosis
- estimating
- indicating instrument
- lithium ion battery
- traction
- road
- highway traffic
- electrification
- electric vehicle
- traffic congestion
- computer science
- software
- automotive engineering
- validation
- design
- energy consumption
- terrain
- public transport
- vehicle fleet
- electric bus
- intelligence
- sensor
- braking
- regenerative braking
- driving
- timetable
- spectroscopic analysis
- spectroscopy
- algorithm
- vehicle
- thermal analysis
- battery charger
- fee
- resistance
- phosphate
- iron
- bicycling
- show 22 more
Publications
- 2022Distal learning of the incremental capacity curve of a LiFePO<sub>4</sub>battery
- 2022Strategies for Minimizing Charging Time in Commercial Nickel-Rich/Silicon-Graphite Lithium-Ion Batteries
- 2022Informed Weak Supervision for Battery Deterioration Level Labeling
- 2020Health Monitoring of Automotive Batteries in Fast-Charging Conditions Through a Fuzzy Model of the Incremental Capacity
- 2020Health assessment of LFP automotive batteries using a fractional-order neural networkcitations
- 2020Mechanistic investigation of silicon-graphite/LiNi<sub>0.8</sub>Mn<sub>0.1</sub>Co<sub>0.1</sub>O<sub>2</sub> commercial cells for non-intrusive diagnosis and prognosiscitations
- 2020Perspective on State-of-Health Determination in Lithium-Ion Batteriescitations
- 2020Online Estimation of the State of Health of a Rechargeable Battery Through Distal Learning of a Fuzzy Modelcitations
- 2019Lithium-Ion Battery Degradation Indicators Via Incremental Capacity Analysiscitations
- 2018Assessing the health of LiFePo<sub>4</sub> traction batteries through monotonic echo state networkscitations
- 2018Main Trends and Challenges in Road Transportation Electrificationcitations
- 2018Design and Validation of a Tool for Prognosis of the Energy Consumption and Performance in Electric Vehiclescitations
- 2018Redesigning European Public Transport: Impact of New Battery Technologies in the Design of Electric Bus Fleetscitations
- 2018Health assessment of automotive batteries through computational intelligence-based soft sensors: An empirical studycitations
- 2018Impact of fast-charging and regenerative braking in LiFePO4 batteries for electric bus applicationscitations
- 2017Lithium-ion battery degradation indicators via incremental capacity analysiscitations
- 2017Operando lithium plating quantification and early detection of a commercial LiFePO4 cell cycled under dynamic driving schedulecitations
- 2017Effect of aging on C/LFP battery impedance: Operating conditions to which the impedance has minimal variationscitations
- 2017Determination of suitable parameters for battery analysis by Electrochemical Impedance Spectroscopycitations
- 2017State of health battery estimator enabling degradation diagnosis: Model and algorithm descriptioncitations
- 2017A Model-Based Virtual Sensor for Condition Monitoring of Li-Ion Batteries in Cyber-Physical Vehicle Systemscitations
- 2016Thermal analysis of a fast charging technique for a high power lithium-ion cellcitations
- 2016Li Plating Quantification in Commercial Graphite‖LiFePO4 cells
- 2016Multiphase resonant converter with output current multiplier for battery charger applicationscitations
- 2016Fast charging technique for high power LiFePO4 batteries: A mechanistic analysis of agingcitations
- 2015Evaluation of LiFePO<sub>4</sub> Batteries for Electric Vehicle Applicationscitations
- 2015Efficient fast-charging strategies for Li-ion batteries
- 2014High power LiFePO<sub>4</sub> cell evaluation: Fast charge, depth of discharge and fast discharge dependencycitations
- 2014DC internal resistance during charge: Analysis and study on LiFePO<inf>4</inf> batteriescitations
- 2014Electric vehicle Li-ion battery evaluation based on internal resistance analysiscitations
- 2013High power LiFePO<sub>4</sub> cell evaluation: Fast charge, depth of discharge and fast discharge dependencycitations
- 2013Fast charging technique for high power lithium iron phosphate batteries: A cycle life analysiscitations
- 2013Evaluation of LiFePO<sub>4</sub> batteries for Electric Vehicle applicationscitations
- 2013Evaluation of LiFePO4 batteries for Electric Vehicle applications
- 2012Evaluation of lithium iron phosphate batteries for electric vehicle under stressful cycling
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