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Full Product Details

Author:   Naoki Matsumura
Publisher:   Artech House Publishers
Imprint:   Artech House Publishers
Edition:   Unabridged edition
Dimensions:   Width: 15.20cm , Height: 2.00cm , Length: 22.90cm
Weight:   0.077kg
ISBN:  

9781630819750

ISBN 10:   1630819751
Pages:   281
Publication Date:   28 February 2023
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Hardback
Publisher's Status:   Active
Availability:   In Print  
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Table of Contents

Chapter 1 - Li-ion Battery Overview and Spec 1.1. Introduction: Battery History to Li-ion Battery 1.2. Structure of Li-ion Battery 1.3. Intuitive Understanding of Charging/Discharging Mechanisms 1.3.1. Charging Mechanism 1.3.2. Discharging Mechanism 1.3.3. Chemical Reactions during Charge and Discharge 1.4. Key Innovations to Realize Li-ion Battery 1.5. Necessary Battery Knowledge to Read a Battery Specification 1.5.2. Battery Terminologies 1.5.4. Battery Cycle Life and Storage Life Spec 1.6. Problems   Chapter 2 - Application of Electrochemistry to Batteries 2.1. Introduction 2.2. Battery Voltage Science and Application 2.2.1. Li-ion Battery Voltage 2.3. Application of Electrochemistry to Battery Design 2.3.1. Faraday’s Law of Electrolysis 2.4. Problems   Chapter 3 - Battery Impedance and Its Impact on Battery Life 3.2.1. Ohm’s Law and IR Drop 3.2.3. Impedance Measurement Method by Electrochemical Impedance Spectroscopy 3.3.1. Battery Discharging under Various Current Rates 3.3.2. Battery Discharging at Various Temperatures 3.3.3. Impedance Dependency on Cycles 3.4. Usable Battery Capacity 3.5. Problems   Chapter 4 - Battery Charging and Impedance Impact 4.1. Introduction 4.2. Li-ion Battery Charging 4.2.1. Constant Current - Constant Voltage Charging 4.3. Fast Battery Charging 4.4. Safe Battery Charging 4.4.1. Safety Guideline and Design 4.4.2. Pre-charge 4.5. Wireless Charging 4.5.1. Introduction 4.5.2. Theory and Structure 4.5.3. Advantages and Disadvantages 4.5.4. Essentials of Wireless Charging for Battery Engineers 4.6. Problems   Chapter 5 - Present and Future Batteries 5.1. Introduction 5.2. Lead-Acid Battery 5.2.1. Reactions 5.2.2. Advantages and Disadvantages 5.3. Ni-MH Battery 5.3.1. Reactions 5.3.2. Advantages and Disadvantages 5.4. Li-ion Battery 5.4.1. Cathode and Anode Options 5.4.2. Details of Cathodes: LCO, NMC, NCA and LFP 5.4.3. Details of Anode: Silicon vs. Graphite 5.4.4. Details of Anode: Lithium Metal 5.4.5. All-Solid-State Battery 5.4.6. Details of Anode: LTO 5.5. Problems   Chapter 6 - Li-ion Battery Cell/Pack Design and Manufacturing/Recycling Process 6.1. Inside of Li-ion Battery 6.1.1. Battery Cell and Pack 6.1.2. Cell Form Factors 6.1.3. Battery Cell Structure 6.1.4. Cell Manufacturing Process 6.1.5. Thin-film Battery Manufacturing Process 6.2.1. Hazardous Situations 6.2.2. Battery Swelling 6.2.3. Safety Protections from Failure Modes 6.2.4. Quality Inspections 6.2.5. Safe Battery Tests 6.3. Battery Pack Configuration 6.3.1. Series and Parallel 6.3.2. Impact of Imbalanced Cells 6.3.3. Shipping Regulations and Battery Certifications 6.3.4. Authentication 6.3.5. Communication Protocol to Battery Pack 6.4. Sustainability and Recycling of Li-ion Batteries 6.5. Problems   Chapter 7 - Battery Fuel Gauging Methods 7.1. Introduction 7.2. Voltage Measurement 7.3. Coulomb Counting 7.3.1. Theory 7.3.2. Advantages and Disadvantages 7.4. Voltage Measurement + Coulomb Counting 7.4.1. Theory 7.4.2. Advantages and Disadvantages 7.5. Impedance Consideration 7.5.1. Theory 7.6. Advanced Fuel Gauging Examples 7.7. State of Health 7.8. System Side Fuel Gauge vs. Pack Side Fuel Gauge 7.9. Problems   Chapter 8 - Fuel Cell 8.1. Introduction 8.2. Hydrogen Fuel Cell 8.2.1. Theory 8.2.2. Structure 8.3. Fuel Cell Characteristics 8.3.1. Current vs. Voltage: I-V Curve 8.3.2. Current vs. Power: I-P Curve 8.3.3. Sporadic Current Change and Voltage Response 8.4. Temperature and Pressure Impacts on Performance 8.4.1. Application of Nernst Equation to Fuel Cell 8.4.2. Pressure Impact on Voltage and Performance 8.4.3. Temperature Impact on Voltage 8.5. Other Fuel Cells 8.5.1. Direct Methanol Fuel Cell (DMFC) 8.5.2. Solid Oxide Fuel Cell (SOFC) 8.6 Fuel Cells Comparison to Li-ion Battery 8.7. Fuel Cell Experiments with a Hydrogen Fuel Cell Kit 8.8. Problems   Chapter 9 - Other Battery-Related Technologies 9.1. Introduction 9.2. Supercapacitors 9.2.1. Theory 9.2.2. Structure 9.2.3. Advantages and Disadvantages 9.2.4. Energy Calculation 9.2.5. Li-ion Capacitor 9.3. Solar Cell 9.3.1. Introduction 9.3.2. Total Energy from the Sun and Efficiency of a Commercial Solar Cell 9.3.3. Theory 9.3.4. Structure 9.3.5. I-V Curve and Maximum Power Point (MPP) 9.3.6. Value of Solar Cell on Electric Vehicle 9.3.7. Transparent Solar Cell 9.3.8. Other Solar Cell Technologies 9.4. Energy Harvesting 9.5. Heat Transfer 9.6. Problems   Chapter 10 - Battery Algorithms for Longevity Estimation and Extension 10.1. Battery Cycle Life and Shelf Life 10.1.1. Battery Longevity Spec 10.1.2. Battery Degradation Mechanism 10.1.3. Degradation Difference by Battery Voltages 10.2. Battery Degradation by Temperatures and its Estimation 10.2.1. Longevity Dependency on Temperature and Arrhenius Equation 10.2.2. Application of Arrhenius Equation to Estimate Battery Degradation 10.2.3. Battery Degradation Estimation by Temperature 10.3. Longevity Extension by Adaptive Charging 10.3.1. Introduction of Adaptive Charging 10.3.2. Adaptive Charging by Scheduling Application 10.3.3. Adaptive Charging through Overnight Charging: Delayed Charging 10.3.4. Adaptive Charging by Situations: Situational Charging 10.4. Problems   Chapter 11 - Battery Application to Various Systems 11.1.1. Battery Usage in Wearables 11.1.2. Method to Extend Battery Life 11.2. Smartphones, Tablets and Laptop PCs 11.2.1. Battery Usage in Portable Systems 11.2.2. Method to Avoid Sudden System Shutdown and Extend Battery Life 11.3. Drones 11.3.1. Battery Usage in Drones 11.3.2. Requirements to Drone Batteries 11.4. Internet Of Things (IOT) Devices 11.4.1. Example of IOT Batteries 11.4.2. Batteries for IOT Devices and Consideration in Selection 11.5. Backup/Stationary Battery 11.5.1. Examples of Backup/Stationary Battery 11.5.2. Requirements to Backup/Stationary Battery 11.6. Batteries for Electric Vehicles (EVs) 11.6.1. EV Battery Usage and Requirements 11.6.2. Algorithms for EV Batteries 11.7. Key Consideration for Longer Battery Life 11.8 Problem   Chapter 12 - AI/Machine Learning/Deep Learning Application to Battery Charging 12.1. Introduction 12.2. Difference between AI, Machine Learning and Deep Learning 12.3. Programming Environment Setup 12.4. Machine Learning (ML) 12.5. Deep Learning (DL) 12.5.1. Neural Network and Deep Learning 12.5.2. DL Applications in the Real World 12.6. Typical Steps in ML/DL Development 12.7. Context-Based Battery Charging: ML/DL Application to Extend Battery Longevity 12.7.1 Introduction 12.7.2 Procedure of Context-Based Battery Charging 12.7.3 Results of Context-Based Battery Charging 12.8. Typical Questions and Answers 12.9 Problem

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