Browse Topic: Electrical, Electronics, and Avionics

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Galvanic Corrosion Susceptibility Analysis and Mitigation strategies in Automotive Battery Packs2026-28-0018To be published on 02/12/2026
As electric vehicles continue to revolutionize transportation, ensuring the reliability of their powertrain systems and battery packs has become a critical focus. One key challenge is galvanic corrosion, which occurs when dissimilar metals in contact are exposed to an electrolyte, such as seashore moisture or road salt used in snow or ice zones. This corrosion can weaken structural components, compromise electrical conductivity, and reduce the lifespan of critical systems. Common areas at risk include metallic joints within battery enclosures, busbars, cooling systems, and electrical connectors. Environmental factors such as high humidity and temperature fluctuations further amplify the issue, making it a pressing concern for manufacturers. This paper aims to systematically identify critical galvanic joints within electric powertrain systems and battery packs and provide effective strategies to mitigate corrosion risks. Preventative measures include choosing compatible materials with
Narain, AdityaVenugopal, SivakumarGopalan, VijaysankarVaratharajan, Senthilkumaran
AI Smart Timer-Based Power Control and Energy Monitoring System for Home Appliances2026-28-0060To be published on 02/12/2026
This paper presents an intelligent home automation system that combines timer-based power control, real-time energy monitoring, and cloud-based AI analytics for individual appliances. The system is built using a Wi-Fi-enabled embedded controller connected to sensing circuits that measure voltage, current, and power consumption. Electromechanical relays are used to control appliance power based on user-defined timers. Users can configure either a fixed runtime or a scheduled cutoff, enabling automated energy-saving without manual input. Alongside local control, the system collects energy consumption data and transmits it to a cloud platform for storage and analysis. A dedicated mobile or web app provides live monitoring, device status, and remote control access. A major innovation is the integration of a cloud-based AI engine that processes historical and real-time data to offer predictive insights. The AI module forecasts energy use, detects anomalies, classifies appliances by behavior
D, AnithaD, SuchitraJain, UtsavMaity, SouvikDinda, Atish
Common Mode Voltage Reduction in Quasi-Z Source Inverter for Electric Vehicle Applications Using MBPWM Technique2026-28-0102To be published on 02/12/2026
Unlike traditional voltage source or current source inverters, ZSI/qZSI can boost and invert DC power in a single stage, making them attractive for applications like EVs where battery voltage may vary. Common mode Voltage (CMV) is the voltage between the neutral point of the motor and ground. High CMV in motor drive systems can cause: Higher leakage currents, Electromagnetic interference (EMI), Insulation stress, bearing currents, leading to premature motor failure. Reducing CMV is essential for reliable and safe EV operation. Pulse-width modulation (PWM) is used to control the QZSI output voltage. The QZSI offers several advantages over traditional inverters, including improved efficiency, reduced cost, and increased reliability. The proposed system is designed to reduce the CMV through a combination of passive LC filtering and shoot-through (ST) modulation techniques. The LC filter is designed to attenuate high-frequency components of the CMV while the ST modulation is used to
N, KalaiarasiR, RajarajeswariD, Anitha
Decentralized Payment Infrastructure for Electric Vehicle Charging via Blockchain and Smart Contracts2026-28-0126To be published on 02/12/2026
As electric vehicles adoption becomes more common, power grid operators are facing new challenges in managing the unpredictable and varying energy demands in the existing electrical infrastructure. Moreover, the cost of Electric vehicle is high when compared to fuel vehicle also it has limited access to charging infrastructure along with the driving range that act as a key barrier preventing the drivers from making shift to EVs. When the EV usage integrates with blockchain, it mitigates the limitation in charging station infrastructure along with the former problem discussed. The lack of trust exists between EV owners and charging station providers can be solved through secure and transparent payment processing possible by blockchain based smart contract. Building charging station on blockchain will ease the automated payment through the use of smart contract and create more efficient EV charging network. Also, the blockchain-based charging system would enable EV owners know if they
Govindasamy, DhivyaR, Rajarajeswari
IoT-Enabled Cloud-Integrated Smart Parking System with Real-Time Monitoring and AI-Based Space Optimization for Next-Gen Mobility2026-28-0113To be published on 02/12/2026
This study presents the design and implementation of an advanced IoT-enabled, cloud-integrated smart parking system, engineered to address the critical challenges of urban parking management and next-generation mobility. The proposed architecture utilizes a distributed network of ultrasonic and infrared occupancy sensors, each interfaced with a NodeMCU ESP8266 microcontroller, to enable precise, real-time monitoring of individual parking spaces. Sensor data is transmitted via secure MQTT protocol to a centralized cloud platform (AWS IoT Core), where it is aggregated, timestamped, and stored in a NoSQL database for scalable, low-latency access. A key innovation of this system is the integration of artificial intelligence (AI)-based space optimization algorithms, leveraging historical occupancy patterns and predictive analytics (using LSTM neural networks) to dynamically allocate parking spaces and forecast demand. The cloud platform exposes RESTful APIs, facilitating seamless
Deepan Kumar, SadhasivamS, BalakrishnanDhayaneethi, SivajiBoobalan, SaravananAbdul Rahim, Mohamed ArshadS, ManikandanR, JamunaL, Rishi Kannan
Development of Multiple level Auto Mode for Climate control in electric vehicles2026-28-0008To be published on 02/12/2026
Electric vehicles, or EVs, are significantly transforming the automotive industry as a cleaner and more environmentally friendly which finds an alternative solution for the vehicles propelled using internal combustion engines. As EV utilize the energy directly from the battery which causes customer or a user to be in panic state as charging infra is not developed well in most of the countries, thus improving vehicle efficiency and driving range requires optimizing energy consumption from battery of EVs. Apart from traction motor load for driving, major supplemental loads in electric car are climate control system, sometimes referred to as HVAC (Heating, Ventilation, and Air Conditioning). HVAC systems can consume a lot of battery power, especially during severe temperatures, which can drastically reduce the vehicle's range. Range anxiety continues to be an important barrier to the general adoption of EVs, the intelligent climate management systems which helps to reduce HVAC power usage
Mulamalla, Sarveshwar ReddySV, Master EniyanM, NisshokAnugu, AnilE A, MuhammedGuturu, Sravankumar
Artificial Intelligence and Cloud Synergy for Scalable Battery Management Systems2026-28-0119To be published on 02/12/2026
Due to a rapid transformation of EV and the battery storage system, the battery management system (BMS) is essential to ensure an optimal performance of the piles of Battery storage. A BMS monitors and controls parameters such as voltage, current and temperature. A traditional BMS has a minimum support of analytics and its limited to local processing. But when the battery information’s are uploaded to the internet, it's easier to manage maintenance and track battery’s performance from anywhere in the world. This IoT /Cloud based system easy and made earlier thereby giving a system alarm before the issue turns big. Management of a lot number of batteries at once saves a lot of money at places like EV charging station and Energy Storage System (BESS). Software updates to the system can also be sent remotely. Also, a BMS connected to cloud can also be used to support weaker grids in an instant if it needs the reactive power support. Cloud integration of BMS with the grid network will help
R, RajarajeswariN, KalaiarasiFrancis, Elgin Calister
MINER’S SAFETY BOT2026-28-0116To be published on 02/12/2026
Mining remains one of the most hazardous industries, with workers constantly exposed to life-threatening conditions such as toxic gases, high temperatures, and confined spaces. To address these concerns, we propose the design and development of an autonomous Miner’s Safety Bot aimed at enhancing underground safety through real-time environmental monitoring and intelligent navigation. The system is built around the ESP32 microcontroller, integrating critical sensors including the MQ7 gas sensor for detecting carbon monoxide and methane, the DHT11 sensor for measuring ambient temperature, and an ultrasonic sensor for obstacle detection. These components work to monitor hazardous parameters and assist the bot in navigating through narrow mine shafts. A servo motor connected to a remote-controlled chassis adjusts the bot's direction when obstacles are detected. The bot employs the ESP32-CAM module to transmit live visuals from the mining site to external observers. Furthermore, sensor data
D, SuchitraD, AnithaMuthukumaran, BalasubramaniamMohanraj, SiddharthSubash Chandra Bose, Rohan
Performance Evaluation of a Novel Coolant Channel Configuration for Liquid-Based Battery Thermal Management in Electric Vehicles2026-28-0042To be published on 02/12/2026
The performance and longevity of lithium-ion (Li-ion) batteries in electric vehicles (EVs) are critically dependent on effective thermal management. As internal heat generation during charge and discharge cycles can lead to uneven temperature distribution, exceeding optimal operating limits (25 - 40°C) can significantly degrade battery performance and lifespan. This study presents a performance evaluation of a novel liquid-based Battery Thermal Management System (BTMS) featuring a dual-directional coolant channel configuration designed to enhance thermal uniformity and heat dissipation. The proposed configuration combines horizontal and vertical coolant passages in an indirect cooling layout to address the limitations of conventional serpentine-type channels. A comprehensive thermal analysis was carried out under realistic loading conditions using three coolant types: water, ethylene glycol-based G48, and graphene-enhanced water nanofluids. These were evaluated for thermal conductivity
Selvan, Arul MozhiPeriyasamy, MuthukumarR, ThiruppathiPrasad S, HariRaghav, RBoddu, Sriram Pydi Aditya
Computational study on dynamic handling performance of a retro-fitted Electric Two wheeler using 125cc powered ICE reference2026-28-0047To be published on 02/12/2026
With the development in motor technology and battery manufacturing technologies, the scope for a budget working EV has been increasing in India. There remains an after-mark potential for conversion of an ICE powered two-wheeler to an EV power train. Such a move reduces the carbon footprint from the vehicle drastically and is still being explored. This study investigates the effect of replacing the ICE with an electric motor in a 125cc motorcycle, with a particular focus on vehicle handling performance using Slalom test. The two wheelers were modelled using calculated mass properties and estimated / calculated moments of inertia using CAD for both ICE and electric powertrains. The electric propulsion system took into consideration the role of a battery pack in the mass and MI calculation. The framework with degrees of freedom is well established in BIKESIMTM simulation environment. A slalom test with automatic gear shift and throttle to maintain speed of the vehicle was set-up to
Sankarasubramanian, HariharanM, ShaghasraV, Ramprathap
Achieving Reliability, Safety & Security in SDV OS Architecture2026-28-0122To be published on 02/12/2026
Software-Defined Vehicles (SDVs) are vehicles in which functionality and features are primarily governed by software, allowing for continuous updates, upgrades, and the introduction of new capabilities throughout the vehicle’s lifecycle. This transition from hardware-centric to software-driven architectures marks a significant shift in the automotive industry, transforming development processes, operational strategies, and business models. The SDV Operating System (SDV OS) is purpose-built for software-defined vehicles, serving as the foundational platform for managing vehicle software and enabling advanced functionalities. Unlike traditional embedded or general-purpose operating systems, SDV OS is tailored to meet the unique requirements of modern automotive architectures. Ensuring reliability, safety, and security is paramount in software-defined vehicles (SDVs), where even minor software faults can lead to serious consequences. The operating system (OS) plays a central role in
Khan, Misbah UllahGupta, Vishal
Multi-Storey AI Based Parking System2026-28-0129To be published on 02/12/2026
This paper presents a comprehensive design and implementation of an AI-based parking management system tailored to address the challenges of modern parking facilities. The system is designed to enhance efficiency, reduce manual intervention, and optimize operational costs while providing a seamless experience for drivers. The core architecture of the system integrates advanced technologies, including computer vision and IR sensors, thereby minimizing reliance on conventional sensors and streamlining the parking process. By leveraging computer vision, the system continuously monitors parking areas in real-time, accurately detecting vehicle occupancy status, and dynamically updating the availability of parking spaces. This real-time monitoring capability enables efficient space utilization, allowing for the optimization of parking resources. In addition to optimizing space allocation, the proposed system prioritizes security through the integration of video surveillance. Utilizing AI
N, KalaiarasiGupta, ShivanshHajarnis, MihirAnand, Vikas
Real time implementation of predictive maintenance for service center automation using Automobile Life Extender (ALE) based on Machine Learning2026-28-0124To be published on 02/12/2026
Automobile Life Extender (ALE) consists of an on-board function, machine learning model operating via cloud computing and a smart phone app. The on-board function will receive signals like engine rpm, throttle position, Brake pedal position, hydraulic pressure etc from vehicles Ecu’s. Based on this data onboard ALE module will calculate the engine load, brake circuit load etc . and sends it to the predictive maintenance model via on board IoT system. The predictive maintenance model will have historical data about the type of engine, brake system and their performance curve data acquired based on test done by its OEM. Here machine learning models play a crucial role in analyzing the vehicle data dynamically, identify drive patterns from it and predict the need for maintenance of a part or a system. A hybrid approach of training models based on Supervised and Unsupervised is incorporated, which will work with certain amount of labeled data along with a set of collected unlabeled data
Sundaram, RameshselvakumarKumar, LokeshSaint Peter Thomas, EdwinSureshkumar, SrihariMuthukumaran, ChockalingamMenon, Abhijith
Virtual Development Kit (VDK) for Software Defined Vehicle2026-28-0120To be published on 02/12/2026
This paper explores the technological and architectural shifts essential for the advancement of Software-Defined Vehicles (SDVs), with an emphasis on decoupling hardware from software. It highlights the constraints of traditional development models and proposes modern architectural approaches, including MPU-based designs and virtualization techniques. Furthermore, it presents strategic pathways to cultivate an open and adaptable development ecosystem, empowering software engineers to experiment, innovate, and drive SDV evolution. These efforts aim to accelerate time-to-market and deliver a superior development experience across the SDV lifecycle. The idea is to develop a Virtual Development Kit (VDK) that enables the design, validation, and scaling of Software-Defined Vehicles (SDVs) even before the physical hardware is available. This comprehensive suite will include hardware platform emulators, operating systems, software stacks, and middleware tailored for high-performance computing
Khan, Misbah UllahGupta, Vishal
STEERING AUTOMATION FOR LANE KEEP ASSISTANCE2026-28-0117To be published on 02/12/2026
The design of advanced driver-assistance systems (ADAS) is essential to improve the safety and autonomy of vehicles in harsh conditions. This work introduces the design and development of a steering automation system for Lane Keep Assistance (LKA) in a vehicle with a parallel steering system. The system utilizes an ArduCam module to take real-time images of the ground in front, and these are processed via machine learning techniques on a Raspberry Pi in order to identify lane edges with great precision. The corrective steering maneuvers are carried out by a motorized steering actuator based on the visual data after processing, and an encoder that is built into the actuator constantly tracks the steering angle and position. This closed-loop feedback affords accurate, real-time corrections to ensure lane discipline without driver intervention. Extensive calculations for steering effort, torque, and gear design confirm the system's mechanical viability. Combining low-cost vision sensing
A R, ArundasSadique, AnwarRafeek, Aayisha
Enhanced Solar Desalination Using Natural Dolomite-Integrated PCM and MWCN Thermal Storage: An Experimental Study2026-28-0082To be published on 02/12/2026
Systems for solar desalination provide a practical and environmentally friendly way to turn salty or polluted water into drinkable water. Three configurations are experimentally investigated in this study: a traditional solar desalination system, a system integrated with a thermal energy storage unit (TESU) based on phase change material (PCM), Multi wall Carbon nano particle were mixed with PCM at 1% of total volume of the PCM and a system that incorporates powdered natural dolomite into the PCM-based TESU. Each of the four configurations was created, tested simultaneously, and thoroughly examined. In comparison to the traditional system, the experimental findings showed that the adoption of PCM-based TESUs increased daily cumulative water output by 11.41%, 14.8% with addition of MWCNT and the addition of dolomite powder further increased productivity by 18.60%. Furthermore, the energy efficiency increased by16.1% with PCM, PCM with MWCNT is increased by 17.43% and 18.18% with the
R L, KrupakaranPetla, RatnakamalaAnchupogu, PraveenP, UmamaheswarraoSatya Meher, RDunna, Vijay
Numerical Study of Battery Pack Cooling for Electric Vehicles2026-28-0110To be published on 02/12/2026
Auto manufacturers are increasingly adopting lithium-ion batteries in response to the rapid evolution of electric vehicle technology. These batteries are being integrated into existing vehicles and planned as the primary power source for new models. Many lithium-ion batteries employ air cooling for safety reasons, due to convenience and cost-effective. This study investigates the cooling efficiency of electric vehicle battery packs using a U-shaped domain with various air-inlet sizes and velocities. Results indicate that air intake position and velocity significantly impact the ability to cool the battery pack. Shifting the air intake point from 30 mm to 20 mm lowers the highest temperature by 3.46 K. Increased air velocity causes a ripple-around effect, reducing the temperature in the second part of the battery pack. Balancing these variables can optimize air circulation and enhance convective heat transfer, potentially improving cooling effectiveness. These insights are valuable for
PC, MuruganJ, SivasankarW, Beno WincyG, Arun Prasad
An Integrated Model Approach for Predicting Vehicle Dynamics Performance during HiL Validation2026-28-0044To be published on 02/12/2026
In the automotive industry, increasing noise regulations are influencing product sales and passenger comfort, creating a need for more effective noise testing methods. Hardware-in-Loop (HiL) based virtual acoustic testing serves as a critical step before Driver-in-Loop testing, allowing for the assessment of noise levels inside and outside the vehicle under various conditions before real-world testing is performed. This study addresses the conversion of a physical vehicle model in the AMESim environment into FMU-RT (Linux) format, and the translation of a powertrain control system from Simulink to C++ code. Key challenges in the FMU-RT conversion include the integration of appropriate submodels for each component and enabling the interfaces necessary for SCANeR and virtual acoustic testing. In the C++ code conversion, challenges involved configuring the correct parameters, ensuring the model runs at a fixed time step and sampling time of 1 ms, and resolving issues related to the
Visuvamithiran, RishikesanChougule, SourabhSrinivasan, RangarajanLaurent, Nicolas
Preliminary Design and Analysis of Dual Throat Fluidic Thrust Vectoring Nozzle for Supersonic Aerospace Application2026-28-0106To be published on 02/12/2026
The project investigates the performance characteristics of dual-throat nozzle used for fluidic thrust vectoring (FTV) in supersonic aircraft applications, offering a potential alternative to mechanical vectoring methods. Fluidic thrust vectoring provides benefits such as reduced weight, lower radar signature, and improved manoeuvrability and control. Computational methods are used to study the effects of geometric and operational parameters, including nozzle pressure ratios and secondary injection rate and injection angle, on thrust-vectoring efficiency and system dynamics. The study aims to develop optimized design configurations and validate using computational models.
Suresh, VigneshM, AkashSenthilkumar, NikilSundararaj, SenthilkumarA, Garry KiristenSingh, Swaraj
Evolution of a Novel Hybrid Stab-Link for a Born Electric Sports Utility Vehicle2026-28-0001To be published on 02/12/2026
The present study details the design evolution and failure analysis of a novel hybrid stabilizer bar link (stab link) developed for the front suspension of a born electric sports utility vehicle (SUV) platform characterized by higher gross vehicle weight (GVW), increased wheel travel, and constrained packaging space. To address these challenges, a unique hybrid stab link was designed featuring dual plastic housings at both the metal ball joint ends, connected by a steel tube, and achieving a 30% weight reduction while offering enhanced articulation angles for extremely lower turning circle diameter (TCD) of the vehicle, compared to the conventional stab link. The unique hybrid stab failed under complex loading conditions during accelerated durability testing (ADT), prompting a comprehensive investigation. The failure analysis included road load data acquisition across various stab bar diameter configurations evolved during suspension tuning, different stabilizer link designs evolved
Selvendiran, PJ, RamkumarNayak, BhargavM, SudhanPatnala, Avinash
Modelling and Analysis of Complex Shaped Cracks2026-28-0048To be published on 02/12/2026
This study offers a thorough analysis using finite element methods (FEA) to examine how fatigue cracks grow in three different materials: Structural steel , Titanium alloy (Ti Grade 2), and epoxy/aramid-based printed circuit board (PCB) laminates. Using ANSYS Workbench, we ran simulations under both static and repeated loading to understand how these materials fracture. The approach was based on Linear Elastic Fracture Mechanics (LEFM), employing the Maximum Circumferential Stress Criterion to predict where cracks might start and how they could spread. Also, the Equivalent Domain Integral (EDI) method helped us calculate the Stress Intensity Factors (SIFs) when cracks are under mixed loading modes. We modeled the growth of fatigue cracks using the Paris Law, relying on material-specific constants (C and m) drawn from previous studies and experimental tests. For example, titanium Grade 2 showed Paris Law constants with C values between 1.8 × 10⁻¹⁰ and 7.9 × 10⁻¹² m/cycle, and m values
T, LokeshBhaskara Rao, Lokavarapu
ACCIDENTAL DOORING WARNING AND ASSIST SYSTEM2026-28-0053To be published on 02/12/2026
The term dooring refers to the accidents where a vehicle door is suddenly opened into the path of an oncoming cyclist or motorcyclist. These issues are serious road safety hazards, especially in congested urban areas where people may be careless. This project proposes an intelligent, computer vision based warning system designed to detect the approaching vehicles and alert the occupants in the vehicle before opening the door. The system uses the rear parking camera in vehicles with rear parking system or a USB webcam in vehicles without rear parking system to capture live video feed, which is processed by a Raspberry Pi 4 microprocessor. The system will run a lightweight deep learning model, MobileNetSSD, through TensorFlow Lite. Detected objects are classified in real time, and the relative distance of other vehicles is estimated using bounding box dimensions. If a vehicle is identified within a preset safety distance threshold, a clear visual warning is displayed to prevent door
C, JegadheesanT, KarthiGurusamy, Varun SankarBalraj, TharunMurugaiya, Tamilselvan
ALTERNATE CATALYST FOR DOC IN A CATALYTIC CONVERTER2026-28-0016To be published on 02/12/2026
Emission norms have become much more stringent to reduce emissions from vehicles. Diesel engines in particular are the predominant contributors to higher emissions. Diesel Oxidation Catalyst (DOC) in diesel engine catalytic converter systems is the crucial component in reducing harmful emissions such as Carbon Monoxide (CO) and unburnt Hydrocarbons (HC). DOCs often rely on expensive noble metals like platinum or palladium and rhodium as catalyst materials,significantly inflating the cost of emission control units. The proposed idea is to explore MnOxCeO₂ (Manganese Oxide-Cerium Oxide) as an alternative catalyst to traditional DOC materials, with the goal of delivering effective oxidation performance while reducing overall system cost. MnOx-CeO₂ catalysts are promising due to their good low-temperature activity, oxygen storage capacity, and redox behaviour, which are beneficial for diesel engines operating under varied conditions. These properties help improve the oxidation of CO and HC
C, JegadheesanT, KarthiRajendran, PawanMuruganantham, KowshiikS, Vaitheeshwaran
Dynamic Stiffness Prediction in Cracked Cantilever Beams Using Enhanced ANN Techniques2026-28-0050To be published on 02/12/2026
This research paper presents an in-depth investigation into the application of Artificial Neural Networks (ANN) for predicting the dynamic stiffness characteristics of cantilever beams affected by cracks of varying depths and positions. Structural failure due to vibration remains a critical concern, and this study focuses on how crack-induced changes in modal stiffness compromise structural reliability. A significant research gap identified in previous studies is the limited consideration of crack location; this work addresses that gap by analyzing how both crack depth and position influence the natural frequency of the beam. Using modal analysis on cantilever beams with identical dimensions but different crack configurations, it was observed that deeper cracks and cracks near the fixed support led to a marked reduction in natural frequency, making the structure more vulnerable to resonance. Cracks located at the free end, however, showed negligible impact. To model and predict these
SB, HarshiniRajkumar, ManjariR, KrithikaK, AnushaK, DivyaBhaskara Rao, Lokavarapu
Reduction of Inductive Losses in Electric Vehicle Wireless Charging through Resonant Coupling2026-28-0123To be published on 02/12/2026
The growing awareness about sustainability and environmental concerns are accelerating the adoption of electric vehicles. They play a promising role due to their potential to significantly reduce greenhouse gas emissions, improve air quality and lessen reliance on fossil fuels. However, one of the primary concerns for potential buyers is the charging process and infrastructure. Traditional wired charging systems for electric vehicles face limitations such as user inconvenience, wear and tear of connectors and challenges in automation. As a solution, wireless electric vehicle charging has emerged, offering a more user-friendly, automated and contactless method of charging by eliminating the need for physical connectors. Wireless charging can be implemented through various approaches, primarily including inductive and resonant methods. Inductive charging suffers from relatively low efficiency due to higher energy losses during transmission. On the other hand, resonant coupling
Shaik, AmjadGudipati, Ravi Sai HemanthB, Vikranth ReddyAnudeep, D B S SVarshith, Dasari
Automotive Ethernet Proxy-Based Security Architecture In Vehicle Computers2026-28-0121To be published on 02/12/2026
Modern vehicles require sophisticated, secure communication systems to handle the growing complexity of automotive technology. As in-vehicle networks become more integrated with external wireless services, they face increasing cybersecurity vulnerabilities. This paper introduces a specialized Proxy based security architecture designed specifically for IP-based communication within vehicles. The framework utilizes proxy servers as security gatekeepers that mediate data exchanges between Electronic Control Units (ECUs) and outside networks. At its foundation, this architecture implements comprehensive traffic management capabilities including filtering, validation, and encryption to ensure only legitimate data traverses the vehicle's internal systems. By embedding proxies within the automotive middleware layer, the framework enables advanced protective measures such as intrusion detection systems, granular access controls, and protected over-the-air (OTA) update channels. This strategy
M, ArvindPraneetha, Appana DurgaRemalli, Ravi Teja
Quantum Meets Agile: Crypto-Agility for a Post-Quantum World2026-28-0127To be published on 02/12/2026
As the automotive industry transitions toward software-defined vehicles and connected ecosystems, cybersecurity becomes a critical design pillar. A pressing challenge emerges with the advent of quantum computing, which threatens to render existing cryptographic standards such as RSA and ECC obsolete. This paper addresses the need for quantum-resilient security architectures in the automotive domain by introducing a combined approach using Post-Quantum Cryptography (PQC) and crypto-agility. Unlike traditional static cryptographic systems, our approach leverages agile architectures that enable seamless integration of new cryptographic algorithms as they emerge. Central to our work is the role of Hardware Security Modules (HSMs), which provide secure, tamper-resistant environments for cryptographic operations within vehicles. We explore how HSMs can evolve into crypto-agile and quantum-safe platforms capable of supporting hybrid and post-quantum algorithms, allowing secure transitions
Kuntegowda, Jyothi
Life Cycle Assessment for Sustainable EV Battery Recycling: A Technical Framework for EBRR.2026-28-0092To be published on 02/12/2026
This technical paper presents a comprehensive framework for implementing a Life Cycle Assessment (LCA) project at EV Batteries Recycling and Regulation (EBRR), focusing on lithium-ion batteries (LIBs) used in electric vehicles (EVs). It identifies key environmental hotspots across resource extraction, battery manufacturing, usage, and end-of-life (EoL) stages. The study evaluates recycling techniques—namely pyrometallurgy, hydrometallurgy, and cascade reuse—to quantify environmental benefits and emission reduction opportunities. The paper uses a cradle-to-grave system boundary with LCA - Ecoinvent datasets, applying ISO 14040/44 standards. Results show that manufacturing accounts for over 60% of life cycle emissions, primarily driven by energy intensity. Transitioning to renewable energy and adopting hydrometallurgical recycling can reduce Global Warming Potential (GWP) by up to 40%. Cascade reuse, when combined with hydrometallurgy, offers the best outcomes with GWP as low as 200 kg
Asokan, GayathriRaju cEng, RajkumarDhananjaya, ChandanSattigeri cEng, Sudhir V
Dual use of Electric Vehicle infrastructure for Enhancing Grid Resilience and Urban Sustainability2026-28-0114To be published on 02/12/2026
The rapid global adoption of Electric Vehicles (EVs) has led to a surge in the deployment of EV charging stations. Beyond their primary role of vehicle charging, these stations hold potential as dynamic, grid-connected assets for sustainable cities and communities (SDG 11). When integrated with renewable energy sources such as wind or solar, EV charging stations can function as decentralized power units, supplying energy to the grid during times of need. This dual functionality allows them to act as flexible loads that mitigate voltage fluctuations during grid faults, facilitating access to reliable energy (SDG 7). Utilizing existing EV infrastructure in this way reduces the need for additional grid-support devices and supports resource efficiency (SDG 13) promoting a low-carbon energy transition. However, their ability to support the grid is limited when fully committed to meeting charging demands, especially during grid faults. To address this challenge, a novel coordinated operation
R, UthraRangarajan, RaviD, SuchitraD, Anitha
A Nature-Inspired Optimization Approach for Vienna Rectifier Control in EV Fast Charging Applications: Performance Comparison with NPC and Swiss Topologies2026-28-0112To be published on 02/12/2026
The growing adoption of electric vehicles (EVs), particularly those utilizing High Voltage battery systems, demands fast-charging infrastructure that ensures high efficiency and power quality. This study proposes a Golden Jackal Optimization (GJO)-based control strategy for a Vienna rectifier used exclusively in a High Voltage EV fast-charging system. Unlike conventional systems that incorporate an additional DC-DC converter stage, the proposed architecture utilizes only the Vienna rectifier for AC-DC conversion, thereby reducing system complexity and improving overall reliability. The GJO algorithm, inspired by the cooperative hunting behavior of golden jackals, is employed to optimize the switching control parameters of the Vienna rectifier, enhancing system performance in terms of efficiency, power factor correction (PFC), and total harmonic distortion (THD). A detailed comparative analysis is performed between the Vienna rectifier, Swiss rectifier, and Neutral-Point Clamped (NPC
R, Mohammed AbdullahN, Kalaiarasi
Effect of Sebastiana rostrata Fiber Loading on the Tribological Behaviour of Polycaprolactone Biocomposite.2026-28-0021To be published on 02/12/2026
This study investigates the tribological performance of Sesbania rostrata fibers (SRFs) reinforced polycaprolactone (PCL) composites, focusing on the effects of fiber loading under varying normal loads. Composite samples with fiber contents of 10%, 20%, and 30% were tested at sliding velocities of 0.5 m/s and a fixed sliding distance of 500 m. Results show that the inclusion of SRFs significantly reduces the coefficient of friction (COF) and specific wear rate (SWR) compared to neat PCL, particularly at fiber loadings up to 20%. Beyond this threshold, fiber agglomeration leads to increased wear. The results highlight the potential of SRF/PCL composites for use in wear-critical automotive and orthopedic applications due to improved load-bearing capability and surface resistance.
Raja, K.Senthil Kumar, M.S.
Electric Vehicle Battery’s Testing Challenges in Era of Software Defined Vehicle2026-26-0159To be published on 01/16/2026
In era of Software Defined Vehicle (SDV), the whole ecosystem of automobile will be impacted. So, it is going to through several challenges for testing activities. In electric vehicle, most critical component is traction battery, which is controlled and operated through battery management system (BMS). BMS is an electronic system, where is going to function as per software of BMS. And in SDV, software is a key element, which is continuously keep on updating on regular basis. So, it means some of BMS functionalities, features or performance may be also altered on each time on software update, which may impact battery’s operating condition, if some scenario is not evaluated during earlier testing then there are it may bring battery out of safe operating area, which may significant impact battery safety, performance or cycle-life. In this paper, we are exploring that different testing requirements for EV Batteries, which may be part of testing practices under era of SDV. Here we will
Bhateshvar, Yogesh KrishanMulay, Abhijit B
Review of Conducted EMI by Different PWM Schemes in the EV Inverters2026-26-0181To be published on 01/16/2026
The advent of wide-bandgap (WBG) switching MOSFET devices enables high-frequency operation, allowing for significant reductions in the size of passive components such as inductors and capacitors, and improving the overall efficiency of inverter systems. However, these benefits come with the trade-off of increased electromagnetic interference (EMI), which imposes stringent requirements on filter design. The complexity of designing EMI filters, which depends heavily on switching frequency and applicable EMI standards, presents a significant challenge and can impact development timelines. Carrier wave modulation technique is considered as an effective method for minimizing conducted EMI in traction inverters. This article presents various carrier wave modulation schemes that successfully reduce conducted EMI. The evaluated strategies aim to eliminate noise fluctuations and simplify the design of demanding EMI filters. Additionally, the impact on output voltage, output current, total
R, KodeeswaranKuncham, Sateesh KumarKolhatkar, Yashomani
State of Health Estimation in Lithium-Ion Batteries: Methods, Comparisons, and Future Directions2026-26-0208To be published on 01/16/2026
As the world is moving towards electric vehicles, we are observing a wide use of Lithium-Ion batteries in modern transportation. Lithium-Ion Batteries offer several advantages over conventional battery systems, including higher energy density that is energy stored per unit mass, longer Cycle Life, faster Charging rates, low Self-Discharge, lighter weight, and ease of maintenance as the memory effect present in other batteries is absent. However, despite these advantages, the system faces significant technical challenges arising from inaccurate battery State of Health (SOH) estimation techniques. These inaccuracies can lead to unexpected vehicle failures and a degraded end-user experience, especially due to incorrect “distance to empty” predictions. In this paper, different SOH estimation techniques are reviewed and compared in detail. The SOH estimation approaches are broadly classified into three main categories: Model based estimation techniques, data driven estimation techniques
Patel, ParvezBhagat, Ayush
State of Health Estimation Based on Dynamic Cell Behaviour in EVs2026-26-0183To be published on 01/16/2026
In electric vehicle (EV) applications, accurate estimation of State of Health (SOH) of lithium ion battery pack is critical for ensuring its performance, reliability, operational safety and user confidence. SOH is a key parameter monitored by Battery Management System (BMS) to check the remaining usable life of the battery and to make informed decisions regarding charging, discharging, power delivery, and maintenance scheduling. In traditional SOH estimation techniques commonly rely on simplistic full-cycle charge-discharge data or single-parameter tracking (such as voltage or internal resistance) and other method like coulomb counting. Kalman filter, model based method such as equivalent circuit modelling, data driven models etc. This methods not consider variable field conditions such as partial and full state of-charge usage condition, dynamic load profiles, and non-uniform aging. As a result, these methods can produce significant deviations in SOH estimation, potentially causing
Nikam, AshishTiwari, Awanish ShankarSodha, NiravHariyani, GaneshAmbhore, Yogesh Gajanan
Resilient Design Strategies for Wireless Charger ECUs: A Proactive Threat Analysis and Risk Assessment Framework for Ensuring Cybersecurity in EV Charging Ecosystems2026-26-0173To be published on 01/16/2026
The proliferation of wireless charging technology in electric vehicles (EVs) introduces novel cybersecurity challenges that require comprehensive threat analysis and resilient design strategies. This paper presents a proactive framework for assessing and mitigating cybersecurity risks in wireless charger Electronic Control Units (ECUs), addressing the unique vulnerabilities inherent in electromagnetic power transfer systems. Through systematic threat modeling, vulnerability assessment, and the development of defense-in-depth strategies, this research establishes design principles for creating robust wireless charging ecosystems resistant to cyber threats. The proposed framework integrates hardware security modules, encrypted communication protocols, and adaptive threat detection mechanisms to ensure operational integrity while maintaining charging efficiency. Experimental validation demonstrates the effectiveness of the proposed security measures in preventing unauthorized access, data
Uthaman, SreekumarMulay, Abhijit BGadekar, Pundlik
Type Approval for ADS: Considerations for the ODD2026-26-0245To be published on 01/16/2026
The rapid introduction of new Automated Driving Systems (ADS) in the last years has led to an urge for robust methodologies for the type approval of vehicles equipped with such technologies. As a result, different Regulations addressing this field have been adopted. These Regulations are mainly based in the New Assessment and Testing Methodology (NATM) developed within the World Forum for the Harmonisation of Vehicle Regulations (WP29). However, the complexity of the regulatory ecosystem extends beyond type approval. This complexity requires a thorough analysis in order to avoid any possible gap which may jeopardise the feasibility of Automated Driving Vehicles deployment. This paper analyses the possible mismatches among the different regulations currently in place or under development and proposes a holistic approach, where the concept of the Operational Design Domain (ODD) takes a relevant role.
Lujan Tutusaus, CarlosHidalgo, JustinFlix, Oriol
Predictive SoC Management for Enhanced Recuperation Efficiency in Electric Vehicles2026-26-0154To be published on 01/16/2026
In recent years, the automotive industry has been looking into alternatives for conventional vehicles to promote a sustainable transportation future having a lesser carbon footprint. Electric Vehicles (EV) are a promising choice as they produce zero tail pipe emissions. However, even with the demand for EVs increasing, the charging infrastructure is still a concern, which leads to range anxiety. This necessitates the judicious use of battery charge and reduce the energy wastage occurring at any point. In EVs, regenerative braking is an additional option which helps in recuperating the battery energy during vehicle deceleration. The amount of energy recuperated mainly depends on the current State of Charge (SoC) of the battery and the battery temperature. Typically, the amount of recuperable energy reduces as the current SoC moves closer to 100%. Once this limit is reached, the excess energy available for recuperation is discharged through the brake resistor/pads. This paper proposes a
Barik, MadhusmitaS, SethuramanAruljothi, Sathishkumar
Improve the Electric Vehicle Range by Using the Climate Control Setting in Economy Mode at Hot Climatic Conditions2026-26-0172To be published on 01/16/2026
Electric vehicles (EVs) have surged in popularity in recent years due to their environmental benefits. The influence of range on air conditioning (AC) power consumption is a critical concern for electric vehicle (EV) owners, particularly in warmer climates. Overcoming obstacles such as a limited vehicle range is necessary for the increased use of electric-powered automobiles. Cabin heating and cooling demand for climate control consumes more energy from the main battery and has been revealed to significantly reduce vehicle range. During peak cooling or heating, the overall power consumption of the AC system takes almost 50% of the energy used for traction. The average reduction in driving range caused by air conditioning (heating and cooling) approximates 33%. The energy usage of an electric vehicle can be considerably decreased by switching the climate control setting to economy mode. The AC system will operate more effectively, enabling the vehicle to save energy and extend its range
Mulamalla, Sarveshwar ReddyAnugu, AnilE A, MuhammedUmmiti, KumarM, NisshokChoudhary, Ankit
Applicability of EMC Validation for EV Powertrain Components2026-26-0197To be published on 01/16/2026
The technology in the automotive industry is evolving rapidly in recent times. An electric vehicle is a complex and dynamic system consisting of numerous components interacting with each other. With increase in number of EVs on Indian roads, EV makers to produce innovative and pragmatic concept of electric vehicle features. This electrification in automobile has brought new dimension to Electro Magnetic Compatibility (EMC). Considering all these, EMC Testing of all power train components with real case scenarios is utmost important. This paper will put a light on applicability of various EMC tests for EV components like Traction Battery, Traction Motor and Inverter, DC to DC Converter, 3 in 1 Unit, 4 in Unit, BTMS unit, HVAC system, On Board Charger etc. With ICE vehicles, all components were connected to only 12V battery but with the EV era, Components are getting connected to HV battery or LV battery or sometimes both. With this change, all ISO and CISPR standards were undergone with
Yeola, MayurMulay, Abhijit BSwaminathan, Ganeshan
Achieving Full ASIL-B Level Functional Safety (FuSa) for Automotive Clusters2026-26-0008To be published on 01/16/2026
Integrating advanced technologies into modern vehicles has led to an increasing focus on Functional Safety (FuSa), especially for the Automotive Integrated Cluster Module (ICM) to ensure the safety of the driver and passengers. This paper highlights the need to bring certain ICM components under an Automotive Safety Integrity Level B (ASIL-B) context using Classic AUTOSAR. This paper discusses the challenges faced and the solutions implemented for achieving compliance with ISO 26262 standards along with the Classic AUTOSAR framework. We are proposing a standardized and structured methodology for the design of the components in compliance with the key safety principles, including Freedom from Interference (FFI), execution under privileged levels, and integrity verification, particularly by adopting Classic AUTOSAR frameworks. This paper also presents the Functional Safety (FuSa) goals for these components and also extend to their configuration management and updating strategies within
Singh, IqbalKumar, Praveen
Digital Control of Synchronous Rectification and Dead Time Configuration for Improving Efficiency and Longevity of DC Motors2026-26-0089To be published on 01/16/2026
This paper elucidates the implementation of software-controlled synchronous rectification and dead time configuration for bi-directional controlled DC motors. These motors are extensively utilized in applications such as robotics and automotive systems to prolong their operational lifespan. Synchronous rectification mitigates large current spikes in the H-bridge, reducing conduction losses and improving efficiency [1]. Dead time configuration prevents shoot-through conditions, enhancing motor efficiency and longevity. Experimental results demonstrate significant improvements in motor performance, including reduced thermal stress, decreased power consumption, and increased reliability [2]. The reduction in power consumption helps to minimize thermal stress, thereby enhancing the overall efficiency and longevity of the motor.
Patil, VinodKulkarni, MalharSoni, Asheesh Kumar
Optimization of Frontal Impact Force Scheme to Accelerate the Target Setting Process for Development of Front-End Structures in Vehicles2026-26-0001To be published on 01/16/2026
A passenger vehicle's front-end structure's structural integrity and crashworthiness are crucial to ensure compliance with various frontal impact safety standards (such as those set by Euro NCAP & IIHS). For a new front-end architecture, design targets must be defined at a component level for crush cans, longitudinal, bumper beam, subframe, suspension tower and backup structure. The traditional process of defining these targets involves multiple sensitivity studies in CAE. This paper explores the implementation of Physics-Informed Neural Networks (PINNs) in component-level target setting. PINNs integrate the governing equations into neural network training, enabling data-driven models to adhere to fundamental mechanical principles. The underlying physics in our model is based upon a force scheme of a full-frontal impact. A force scheme is a one-dimensional representation of the front-end structure components that simplifies a crash event's complex physics. It uses the dimensional and
Gupta, IshanBhatnagar, AbhinavKumar, Ayush
Analysis of Road Accident Statistics for Females in India and Gaps in Safety Regulations2026-26-0020To be published on 01/16/2026
This paper investigates the current state of road safety for female occupants in India, with a particular focus on road accident statistics and the gaps in safety regulations. According to the Road Accident in India 2022 report by the Ministry of Road Transport and Highways (MoRTH), female occupants constitute 16% of passenger car fatalities. Using a extensive dataset of 596 passenger car accidents involving at least one female occupant from the Road Accident Sampling System – India (RASSI), this study evalu the severity and patterns of injuries sustained by female drivers and passengers. The analysis identifies critical shortcomings in existing safety measures, particularly in addressing anatomical differences and male-centric safety designs. Gender-sorted injury trends reveal heightened vulnerabilities for women in crash scenarios. Current regulatory frameworks bank on crash test dummies developed on average male anthropometry, neglecting female-specific biomechanical needs in
Ayyagari, ChandrashekharG, Santhosh KumarRao, Guruprakash
Analysis of Energy Consumption for Heating City Electric Buses and Ways to Reduce It2026-26-0156To be published on 01/16/2026
For regions with cold climate, the range of an electric bus becomes a serious restriction to expanding the use of this type of transport. Increased energy consumption affects not only the autonomous driving range, but also the service life of the batteries, the schedule delays and the load on the charging infrastructure. The aim of the presented research is to experimentally and computationally determine the energy consumption for heating the driver's cabin and passenger compartment of an electric bus during the autumn-winter operation period, as well as to identify and analyze ways to reduce this energy consumption. To determine the air temperature in the passenger compartment, a mathematical model based on heat balance equations was used. This model was validated using data from real-world tests. The research was conducted at a proving ground under two conditions: driving at a constant speed and simulating urban bus operation with stops and door openings. The causes of heat loss in
Kozlov, AndreyTerenchenko, AlexeyStryapunin, Alexander
A Comprehensive Study: The Potential of Wireless Charging in Future E Mobility2026-26-0195To be published on 01/16/2026
Electric mobility is no longer a distant vision, it is a global imperative in the journey of fight against the climate change and the urban pollution. Yet, despite of explosive growth in the electric vehicle adoptions, a major bottleneck remains which is efficient and convenient charging. The current reliance on physical plug in charging station creates inconvenient, time consuming experience and also faces significant technical and economic challenges those threaten to stall the smooth clean transportation revolution. Without innovation in how we recharge our vehicle the promise of electric mobility appears under threat which is undermined by less efficient, less compatible, and infrastructure hurdles. Wireless charging technology stand out as the game changing breakthrough poised to tackle these all critical problems head on. By enabling the effortless, cable-free charging system across the wide spectrum of electric vehicles, from the personal cars to the public transport fleets and
Jain, GauravPremlal, PPathak, RahulGore, Pandurang
Early Prediction of Relaxation Voltage & Detection of State of Battery for Functional Safety2026-26-0166To be published on 01/16/2026
During parking conditions of vehicles, the state of the battery is uncertain as it goes through the relaxation process. In such scenarios, the battery voltage may exceed the functional safety limits. If we cross the functional safety limits, it is hazardous to the driver as well as the occupant. In this case, relaxed voltage plays a crucial role in identifying the safe state of the battery. To estimate the relaxed cell voltage there are methods such as RC filter time constat modeling and relaxation voltage error method. The problem with these solutions is the waiting time and accuracy to determine the relaxation voltage. In this manuscript, a solution is proposed which ensures the above problem is reduced. To achieve the reduction of relaxation voltage estimation time, a python sparse identification of nonlinear dynamics (PySindy) is used which identifies and fits an equation model based on observing the battery characteristics at different SOC and temperatures. The implementation is
Pandey, PriyanshuNilajkar, AnkurPanda, Abinash
Thermal Management Control Strategy for Primary & Secondary Drive Cooling Hybrid Electric Tractor2026-26-0069To be published on 01/16/2026
Global emission norms are getting very strict due to combat the harmful pollutants from internal combustion engine. Hence internal combustion engine (ICE)-based agricultural tractors need to introduce complex after-treatment systems and fuel optimization to provide same or higher value to farmers as cost of these systems drive the overall cost of the product. Engineers around the world are building Electric vehicles to combat the problem and has range issues due to design constraints & Hybrid tractors have emerged as a promising intermittent solution. It helps in combining the advantages of respective ICE and electrification solutions while reducing overall vehicle emissions and enhances operational flexibility. This paper presents a modular thermal modes system developed for a hybrid electric tractor platform where a downsized diesel engine operates at optimal efficiency DC generator used to charge the battery & DC converter is used to charge the auxiliary battery. Battery which is
K, SunilD, MariNatarajan, SaravananKumawat, Deepakrojamanikandan, ArumughamK, MalaV, SridharanMuniappan, BalakrishnanMakana, Mohan
Advanced SVPWM Techniques for Multi-Level Inverters: Enhancing Performance and Reducing Complexity2026-26-0147To be published on 01/16/2026
Over the last few years, notable progress has occurred in electric vehicle (EV) technology. Inverters are key components for electric vehicles (EV). Various PWM strategies have been implemented by OEMs over past years. For most of PWM scheme timing calculation & Lengthy algorithm increases complexity. The proposed a novel Pulse Width Modulation (PWM) control technique for generating inverter lag switching times in multi-level inverters. The proposed Space Vector PWM (SVPWM) method eliminates the need for sector and region identification by utilizing sampled values of reference phase voltages, thereby reducing computational efforts and complexities. The scheme can generate N-level PWM signals and offers flexibility to operate with fewer levels, including operation in the overmodulation range. The sampled magnitudes reference phase voltages are converted into timing signals that are subsequently processed by an algorithm to modify modulating signals. These modulating signals are
Bhanabhagvanwala, Prem Kiritkumar
Integration and Proving Ground Evaluation of a Connected Highway Pilot System2026-26-0136To be published on 01/16/2026
Highway Pilot (HWP) systems, classified as SAE Level 3 Automated Driving Systems (ADS), represent a potential advancement for safer and more efficient highway drives. In this work, the development of a connected HWP prototype is presented. The HWP system is deployed in a real test vehicle and designed to operate autonomously in highway environments. The implementation presented in this paper covers the complete setup of the vehicle platform, including sensor selection and placement, hardware integration and communication interfaces for both autonomous functionality and Vehicle-to-Everything (V2X) connectivity. The software architecture follows a modular design, composed of modules for perception, decision-making and motion control to operate in real-time. The prototype integrates Vehicle-to-Vehicle (V2V) communication, such as Cooperative Awareness Messages (CAM), to enhance situational awareness and improve the overall system behaviour. The modular structure allows new functionalities
Domingo Mateu, BernatLeiva Ricart, GiselaFacerias Pelegri, MarcPerez, Marc
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