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Virtual Evaluation of Ceramic Glow Plug Design using Multiphysics Simulation Approach

2025-01-8367To be published on 04/01/2025

A glow plug is generally used to assist the starting of diesel engines in cold weather condition. Low ambient temperature makes the starting of diesel engine difficult because the engine block acts as a heat sink by absorbing the heat of compression. Hence, the air-fuel mixture at the combustion chamber is not capable of self-ignition based on air compression only. Diesel engines do not need any starting aid in general but in such scenarios, glow plug ensures reliable starting in all weather conditions. Glow plug is actually a heating device with high electrical resistance, which heats up rapidly when electrified. The high surface temperature of glow plug generates a heat flux and helps in igniting the fuel even when the engine is insufficiently hot for normal operation. Durability concerns have been observed in ceramic glow plugs during testing phases because of crack formation. Root cause analysis is performed in this study to understand the probable reasons behind cracking of the

Karmakar, Nilankan, orban, Hatem

Enhancing and Validating Numerical Models for Oil-Jet Cooing on Corrugated Surfaces of Electric Motor Windings

2025-01-8160To be published on 04/01/2025

The U.S. DRIVE Electrical and Electronics Technical Team has set a goal for 2025 to achieve a power density of 33 kW/L for electric vehicle (EV) motors. The increase in motor power density is highly dependent on effective thermal management within the system, making active cooling techniques like oil-jet impingement essential for continued advancements. Due to the time and expense of physical experimentation, numerical simulations have become a preferred method for design testing and optimization. These simulations often simplify the motor-winding surface into a smooth cylinder, overlooking the actual corrugated surface due to windings, thus reducing computational resources and mesh complexity. However, the coil's corrugated surface affects flow turbulence and heat transfer rates. This study utilizes three-dimensional Computational Fluid Dynamics (CFD) simulations to investigate the impingement-cooling of an Automatic Transmission Fluid (ATF) jet on a corrugated surface that replicates

Mutyal, Jayesh Ramesh, Gurunadhan, Mohana, haghnegahdar, Ahmad, Champhekar, Omkar, Konangi, Santosh

Modal Characteristics of Oil-Gas Interconnected Suspension Systems and Their Influence on Vehicle Ride Quality

2025-01-8271To be published on 04/01/2025

Oil-air interconnected suspension technology has attracted much attention because of its superior dynamic adjustment capability. In this paper, four kinds of oil-air interconnected suspensions with front and rear interconnections and accumulator volume sizes are studied as objects, and a multi-body dynamics model of automobile and a hydraulic model of oil-air interconnected suspensions are established to analyze the bias frequency of suspensions and the vibration modes of the vehicle body. Impulse excitation and random road conditions were designed to analyze the vehicle dynamics response under each configuration in terms of frequency and mode, and the excitation state of each mode of the body was analyzed under different conditions. The analysis provides a theoretical basis for the system design and smoothness optimization of the oil-air interconnected suspension

Xinrui, Wang, Chen, Zixuan, Zhang, Yunqing, Wu, Jinglai

Headliner design considerations to meet safety and regulations

2025-01-8245To be published on 04/01/2025

Headliners are one of the largest components inside an automobile, stretching from the front windshield to the rear windshield. Besides its aesthetic purpose, it contributes to multiple other purposes like housing different components, helps in NVH, defines the interior roominess, and plays a crucial role in defining the deployment of curtain airbag. The headliner also plays a role in meeting regulatory requirements like upward visibility and headroom requirements of the occupants. During the deployment of curtain airbag, it is important that the headliner-pillar interface aids in the easy opening of airbag, with the least hindrance. This is defined by multiple factors like the location of headliner-pillar interface in “z” direction, and its distance from the airbag ramp bracket, the position of the inflator, the mountings of the headliner and pillar trims, to name a few. Also, during the deployment of the airbag, it is important that parts such as grabhandle, speaker grilles, etc

Sabesan, Arvind Kochi, D., Anantha, Kakani, Phani Kumar

Intebrake 3-D CFD Transient Simulation Studies for Predicting Flow Performance

2025-01-8362To be published on 04/01/2025

This paper presents transient, complex, moving mesh, 3-D CFD analysis of an intebrake lubrication oil circuit for predicting flow performance. Intebrake is a mechanism for improving braking performance during over speeding conditions. The mechanism briefly opens the exhaust valve at the end of a compression stroke with a small valve lift and releases the compressed gases, thereby helping in quick application of the brake. There is no fueling during the process and hence, no combustion induced pressure rise which helps in quick application of the brake. During the intebrake operation, opening of the exhaust valve is achieved by using a complex lube oil circuit inside the exhaust rocker lever. The intebrake lube oil circuit consists of various spring-operated valves with micro-sized clearances, high oil pressure generation up to ~ 250 bar, 3-D movement of the mechanism components, and it is a transient operation. The 3-D movement consists of simultaneous rotational and translational

Tawar, Ranjit Ramchandra, Pasunurthi, Shyam Sundar, Bedekar, Sanjeev, Ranganathan, Raj

Evaluating the Potential of a Turbo-compound System for a Heavy-Duty Natural Gas Engine: A Modelling Study

2025-01-8355To be published on 04/01/2025

Combining a low-carbon content fuel, such as natural gas, with a high-efficiency engine can reduce greenhouse gas emissions significantly in hard-to-electrify long-haul trucking applications. Turbo-compounding, where an additional power turbine is installed in the exhaust stream after the turbocharger turbine, can extract useful amounts of energy from diesel engine exhaust at high loads. This work assesses the net benefits of combining turbo-compounding with a high-efficiency, natural gas fuelled heavy-duty engine. The effects on brake specific fuel consumption (BSFC), greenhouse gas emissions, and engine-out emissions of nitrogen oxides (NOx) and methane (CH4) are considered. The experimentally validated 1D model for a 13L diesel pilot- direct injection of natural gas, heavy-duty engine in GT-SUITETM is used to develop a series turbo-compound model. The effects of turbine sizes and flow capacities in fixed-geometry turbocharging and power turbines are evaluated on the engine’s

Balazadeh, Navid, Munshi, Sandeep, Shahbakhti, Mahdi, McTaggart-Cowan, Gordon

Artificial Intelligence Technique Applied to Semi-Active Vibration Control of Vehicle Suspension Systems

2025-01-8270To be published on 04/01/2025

The study investigates to quantify the benefits of magnetorheological (MR) dampers in enhancing ride comfort, vehicle stability, and overall system performance in semi-active suspension systems. Magnetorheological (MR) dampers in semi-active suspension systems work together with active and passive suspension technologies to make them more effective and flexible. The study investigates to quantify the benefits of magnetorheological (MR) dampers in enhancing ride comfort, vehicle stability, and overall system performance in semi-active suspension systems. Magnetorheological (MR) dampers in semi-active suspension systems work together with active and passive suspension technologies to make them more effective and flexible. The complete dynamic system model encompasses essential performance parameters such as seat travel, body acceleration, passenger acceleration, suspension travel, and tire deflection. This research reveals that the suggested artificial intelligence, such as a variable

M.Faragallah, Mohamed, Metered, Hassan, Abdelghany, M.A., Essam, Mahmoud A.

Research on Turbocharger Surge Identification and Prediction Based on Acoustic Signal

2025-01-8253To be published on 04/01/2025

This study presents a non-intrusive method for detecting surge in diesel engine turbochargers using acoustic signal analysis. We introduce an innovative surge identification approach that leverages multi-domain composite features derived from these acoustic signals. The research involved conducting controlled turbocharger surge experiments, which provided the data necessary to develop a comprehensive surge acoustic signal database. From this database, eighteen acoustic features were meticulously selected and extracted across both time and frequency domains. Their relevance to surge detection was evaluated using a random forest algorithm, enabling the identification of key features critical to accurate detection. These essential features were then integrated into a multi-domain composite feature set, which served as the sensitive indicator for turbocharger surge detection. During the model development phase, we systematically compared the performance of various machine learning

Zhu, Jiaxu, Zheng, Hongyu, Zong, Changfu

Design of Road Sense Simulation Method for Automobile Front Wheel Steer-By-Wire System

2025-01-8260To be published on 04/01/2025

With the continuous development of electronic control technology in the automobile industry, the integration of electronic components in the automobile control system is increasing day by day, which significantly improves the safety performance and handling stability of the automobile. After entering the 21st century, the rapid development of intelligent technology makes the steer-by-wire system gradually integrated into modern automobile design. Because the steer-by-wire system cancels the mechanical connection between the steering wheel and the steering wheel in the traditional mechanical steering system, various road information on the road can’t be directly transmitted to the driver through the steering wheel in the form of road sense, and the driver can’t truly feel the road information, which is not conducive to the driver's control of the car. Therefore, this paper studies the road sense simulation method of steer-by-wire system. Firstly, the dynamic model of the steer-by-wire

Li, Xuesong, Li, Zhicheng, Zheng, Hongyu, Kaku, Chuyo

A Control and Fault-Tolerant Strategy Based on Electromechanical Brake System

2025-01-8265To be published on 04/01/2025

With the development of automobile electrification and intelligent technology, vehicles have higher and higher requirements for braking systems. On the one hand, they are required to have active braking functions and be easy to integrate with other control systems in the chassis domain; on the other hand, the system is required to minimize oil pollution and be able to recover as much braking energy as possible in cooperation with the upper-level control strategy under the premise of ensuring pedal force to increase the cruising range of electric vehicles. The composite braking system based on electromechanical brake (EMB) is a wire-controlled decoupled composite braking system that can not only meet the needs of brake pedal feel, but also achieve continuous and precise control of composite braking force, and can effectively take into account the braking energy recovery rate, braking safety and braking comfort. In addition, the current EMB technology is still immature and has a high

Li, Xuesong, Qin, Keyun, Zheng, Hongyu, Kaku, Chuyo

Market Research & Analysis of failures due to environmental gases in Automotive Electronics and integration of learnings in development testing

2025-01-8255To be published on 04/01/2025

Automotive industry is growing rapidly with innovations leading to increase in new features and improving the Quality of vehicles. These new components are developed with the available design standards across global OEMs. This Quality research paper aims to address the need of revision of design standards due to environmental factors prevailing in India. With the increase towards autonomous mobility, the number of electronics is also increasing, and this involves hardware & software evaluation. The hardware testing is a point of concern due to increase in the failure rate from the markets. Environment changes are very much evident with the growing economies and OEMs are developing the components with innovation, but if the basic design standards are not revised in parallel with the changing environment, the issues will continue to trouble the end customers. The failed cases data received from across the country was analyzed and observed that the cases are majorly reported from urban

Marwah, Ramnik, Pyasi, Praveen, Bindra, Ritesh, Garg, Vipin

Development of Prediction Model for Vehicle Road Load Using Machine Learning

2025-01-8258To be published on 04/01/2025

In the modern automotive industry, improving fuel efficiency while reducing carbon emissions is a critical challenge. To address this challenge, accurately measuring a vehicle’s road load is essential. The current methodology, widely adopted by national guidelines, follows the coastdown test procedure. However, coastdown tests are highly sensitive to environmental conditions, which can lead to inconsistencies across test runs. Previous studies have mainly focused on the impact of independent variables on coastdown results, with less emphasis on a data-driven approach due to the difficulty of obtaining large volumes of test data in a short period, both in terms of time and cost. This paper presents a road load energy prediction model for vehicles using the XGBoost machine learning technique, demonstrating its ability to predict road load coefficients. The model features 27 factors, including rolling, aerodynamic, inertial resistance, and various atmospheric conditions, gathered from a

Song, Hyunseung, Lee, Dong Hyuk, Chung, Hyun

Research on the Parameter Optimization Method for a Dual-Motor Coupled Integrated Single-Axle Drive System

2025-01-8284To be published on 04/01/2025

This paper explores a parameter optimization calculation method for a dual-motor coupled integrated single-axle drive system, aiming to achieve the optimal balance between vehicle dynamics, fuel efficiency, and system efficiency under this configuration. By constructing a vehicle longitudinal dynamics model and referencing motor models, the effective operating range is calculated. Vehicle acceleration time, gradeability, and maximum speed are used as constraints, while the proportion of the high-efficiency operating area of the drive system is taken as the objective function for optimizing relevant system parameters. This method improves computational efficiency by dividing the contour lines, thus eliminating the need to traverse all points in the constraint area and converting them into an intuitive analysis of the operating range, which reduces the need for point-by-point calculations across the entire working area

Gu, Zhuangzhuang, You, Jianhui, Wu, Jinglai, Zhang, Yunqing

A Suspension Model Based on Semi-Recursive Method and Data-Driven Compliance Characteristics

2025-01-8282To be published on 04/01/2025

Many methods have been proposed to accurately compute a vehicle’s dynamic response in real-time. The semi-recursive method, which models using relative coordinates rather than dependent coordinates, has been proven to be real-time capable and sufficiently accurate for kinematics. However, not only kinematics but also the compliance characteristics of the suspension significantly impact a vehicle’s dynamic response. These compliance characteristics are mainly caused by bushings, which are installed at joints to reduce vibration and wear. As a result, the use of relative or joint coordinates fails to account for the effects of bushings, leading to a lack of compliance characteristics in suspension and vehicle models developed with the semi-recursive method. In this research, we propose a data-driven approach to model the compliance characteristics of a double wishbone suspension using the semi-recursive method. First, we create a kinematic double wishbone suspension model using both the

Zhang, Hanwen, Duan, Yupeng, Zhang, Yunqing, Wu, Jinglai

A Comparison of UAV LiDAR and Terrestrial Laser Scanner Accuracies

2025-01-8694To be published on 04/01/2025

The accident reconstruction community frequently uses Terrestrial LiDAR (TLS) to capture accurate 3D images of vehicle accident sites. This paper compares the accuracy, workflow, benefits, and challenges of Unmanned Aerial Vehicle (UAV) LiDAR, or Airborne Laser Scanning (ALS), to TLS. Two roadways with features relevant to accident reconstruction were selected for testing. ALS missions were conducted at an altitude of 175 feet and a velocity of 4 miles per hour at both sites, followed by 3D scanning using TLS. Survey control points were established to minimize error during cloud-tocloud TLS registration and to ensure accurate alignment of ALS and TLS point clouds. After data capture, the ALS point cloud was analyzed against the TLS point cloud. Approximately 80% of ALS points were within 1.8 inches of the nearest TLS point, with 64.8% at the rural site and 59.7% at the suburban site within 1.2 inches. These findings indicate that UAV-based LiDAR can achieve comparable accuracy to TLS

Foltz, Steven, Terpstra, Toby, Clarson, Julia

High Performance Computer Based Software Defined Vehicle Hardware in the loop testing

2025-01-8137To be published on 04/01/2025

Recent years have seen a strong move towards Software Defined Vehicle concept as it is seen as an enabler for advancing the mobility by integrating complex technologies like Artificial Intelligence (AI) and Connected Autonomous Driving (CAD) into the vehicle. However, this comes with fundamental changes to the vehicle’s Electrical/Electronic (EE) architecture which require novel testing approaches. This paper presents FEV’s SDV Hardware-In-The-Loop (HIL) test setup which focuses on testing the developed HPC-based software. The functionality of the SDV HIL test setup is demonstrated by testing the software of multiple technologies within the HPC environment like ADAS and teleoperation virtual control units with OTA capability. Test results show the effectiveness of utilizing FEV’s HIL setup in developing and validating the software of SDV platforms

Obando, David, Alzu'bi, Hamzeh, Carreón Vásquez, Erwin, Alrousan, Qusay, Alnajdawi, Mohammad Sami, Tasky, Thomas

On the Characterization and Optimization of Machining Chip Washing System Using Multi-Variable Response Surface and Gradient Descent Method

2025-01-8637To be published on 04/01/2025

The final step in manufacturing high-precision parts for internal combustion engines, such as cylinder heads and blocks, is the removal of machining chips from the finished parts. This step is crucial because the machining chips and cutting oil left on the surface after machining can cause quality issues in the downstream engine assembly and affect the cooling system’s performance during engine operation. This chip removal step is especially critical for parts with internal cavities, such as the water jackets in cylinder heads, due to the difficulty of removing chips lodged in the narrow passages of these internal channels. To effectively remove chips from the water jacket, machining chip washing systems typically utilize multiple high-velocity water jets directed into the water jacket, creating flows with substantial kinetic energy to dislodge and evacuate the machining chips. For machining chip washing systems equipped with dozens of water nozzles, optimizing washing efficiency

Jan, James, Torcellini, Sabrina, Khorran, Aaron, Hall, Mark

Study of Indian Population’s Eye Point to Adapt Indian Vehicle Design to Indian Anthropometry for Accident Risk Mitigation

2025-01-8665To be published on 04/01/2025

India has one of the highest accident rates in the world. Quite a few accidents have been attributed to poor driver visibility. Driver visibility is an important factor that can help mitigate the risk of accidents. The optimal visibility of in-vehicle controls is also essential for improving driver experience. Optimized driver visibility improves driving comfort and gives confidence to the driver, ensuring the safety of drivers and subsequently that of pedestrians. Driver visibility is an important consideration for vehicle occupant packaging and SAE has defined various standards and regulations for the same. These guidelines are defined considering American anthropometry, helping OEMs create global vehicles with uniform checkpoints. However, due to anthropometric differences, a need was felt to capture and analyze Indian-specific eyellipse and eye points. To measure the eye point of the user in a controlled environment, the interiors of a passenger vehicle were simulated using a

P H, Salman, Kalra, Prerita, Rawat, Ashish, Sharma, Deepak, Singh, Ashwinder

Development of a Detailed Ignition Model with Energy Deposition and its Application to Full Engine Simulation

2025-01-8360To be published on 04/01/2025

A multi-dimensional model of the spark ignition process for SI engines was developed as a user-defined function (UDF) integrated into the commercial engine simulation software CONVERGE CFD. The model presented in this paper simulates energy deposition from the ignition circuit into the fuel-air mixture inside the cylinder. The model is based on interaction and collision between electrons in the plasma arc and the gas molecules inside the cylinder using parameters from the ignition circuit and gas inside the cylinder. Full engine simulations using CONVERGE CFD with the developed ignition model including the ignition circuit model, arc propagation model, and energy deposition model were performed to evaluate the validity and performance of the model and to compare with the ignition model provided by CONVERGE CFD. Two engines with different characteristics were used for comparison, a low turbulent port fuel injected single-cylinder CFR engine and a high turbulent direct injected engine

Kim, Kyeongmin, Hall, Matthew, Joshi, Sachin, Matthews, Ron

Identifying Negative Driver States that Share Commonalities for Interventions

2025-01-8676To be published on 04/01/2025

Advancements in sensor technologies have led to increased interest in detecting and diagnosing "driver states"-collections of internal driver factors generally associated with negative driving performance, such as alcohol intoxication, cognitive load, stress, and fatigue. This is accomplished using imperfect behavioral and physiological indicators that are associated with those states. An example is the use of elevated heart rate variability, detected by a steering wheel sensor, as an indicator of frustration. Advances in sensor technologies, coupled with improvements in machine learning, have led to an increase in this research. However, a limitation is that it often excludes naturalistic driving environments, which may have conditions that affect detection. For example, reductions in visual scanning are often associated with cognitive load (e.g., Angell et al., 2015); however, these reductions can also be related to novice driver inexperience (e.g., Stahl et al., 2019) and alcohol

Seaman, Sean, Zhong, Peihan, Angell, Linda, Domeyer, Joshua, Lenneman, John

Solving Vehicle Speed and Acceleration from Video Evidence Using Optimization

2025-01-8683To be published on 04/01/2025

This paper introduces a method to solve vehicle dynamics from one or more sources of video evidence by using optimization to determine the best-fit speed profile that tracks the measured path of a vehicle through a scene. Mathematical optimization is the process of seeking the variables that drive an objective function to some optimal value, usually a minimum, subject to constraints on the variables. In the video analysis problem, the analyst is seeking a speed profile that tracks measured vehicle positions over time. Measured positions and observations in the video constrain the vehicle’s motion and can be used to determine the vehicle dynamics. The variables are the vehicle’s initial speed and an unknown number of acceleration sequences. Optimization can be used to determine the speed profile that minimizes the total error between the vehicle’s calculated travel distance at each measured position, subject to various constraints. A test was designed to demonstrate the proposed method

Snyder, Sean, Callahan, Michael, Wilhelm, Christopher, Johnk, Chris, Lowi, Alvin, Bretting, Gerald

Impacts of injection pressure on split-injection energy-assisted compression-ignition combustion of low cetane number SAFs with a Gaussian-shaped ribbed piston bowl design

2025-01-8350To be published on 04/01/2025

The impacts of injection pressure on a split-injection strategy used to enable mixing-controlled combustion of low cetane number sustainable aviation fuels using energy-assisted compression-ignition (EACI) operation with a Gaussian-shaped ribbed piston bowl design were investigated in an optically accessible research engine. Three injection pressures (600, 800, and 1000 bar) were investigated at three split-injection dwells (1.5, 2.0, and 2.5 ms) with a fixed second injection timing of -5.0 CAD. A Gaussian-shaped ribbed piston bowl design was employed to reliably position hot combustion gases from the first injection near the centrally located injector to enable rapid ignition and mixing-controlled combustion of the second injection. Results indicate that as injection dwell was shortened, relocation of hot combustion gases near the injector became increasingly more difficult due to the higher in-cylinder densities at start-of-injection (SOI) of the first injection. However, results

Amezcua, Eri, Stafford, Jacob, Kim, Kenneth, Kweon, Chol-Bum, Rothamer, David

Predicting Forming Limit of Hot Stamping Boron Steel using a Modified Zener-Hollomon Parameter based Ductile Failure Criterion

2025-01-8225To be published on 04/01/2025

This study combines a recently proposed ductile failure criterion with a modified Zener-Hollomon parameter to predict the forming limit of a boron steel at hot stamping temperatures. The Zener-Hollomon parameter is modified to include a parameter that accounts for the non-linear variation of strain rate during hot stamping. The combined ductile failure criterion takes into account the critical damage at localized necking or at fracture as a function of strain path, initial sheet thickness and strain rate variation. The process of determining various parameters in the failure criterion is explained. The capability of the ductile failure criterion is demonstrated by predicting forming limit of a boron steel in an isothermal Nakajima dome test. The criterion is further demonstrated by predicting fracture in hot stamping a B-Pillar part (NUMISHEET Benchmark #3 2008

Sheng, ZiQiang, Mallick, Pankaj

Combine HD map information to enhance road topology reasoning by offline supervised training and on-line ensemble learning

2025-01-8021To be published on 04/01/2025

Topology reasoning plays a crucial role in understanding complex driving scenarios and facilitating downstream planning, yet the process of perception is inevitably affected by weather, traffic obstacles and worn lane markings on road surface. Combine pre-produced high-precision maps, and other type of map information to the perception network can effectively enhance perception robustness, but this on-line fused information often requires a real-time connection to website servers. We are exploring the possibility to compress the information of offline maps into a network model and integrate it with the existing perception model. We designed a topology prediction module based on graph attention neural network and an information fusion module based on ensemble learning. The module, which was pre-trained on offline high-precision map data, when used online, inputs the structured road element information output by the existing perception module to output the road topology, and the output

Kuang, Quanyu, Rui, Zhang, Zhang, Song, Yixuan, Gao

Enhancement in Cabin Comfort and Overall Energy Utilization of an Electric Reverse Trike Car by Optimizing the System Layout

2025-01-8150To be published on 04/01/2025

As the emissions norms are getting stringent and stricter, the use of all electric vehicles is widespread and becoming mainstream mobility both in urban and rural areas. However, lack of good charging infrastructure and high energy density cells limiting the overall electric mobility eco-system. Eventually the shorter range and high charging time of the vehicle is becoming the key challenge of e-mobility. Energy consumption by one of the key auxiliary systems e.g. air-conditioning (AC) system is adding further concerns over the range anxiety. It is the most energy consuming system among all others. Hence the need of the hour is to improve and enhance the AC system performance by means of redefining and optimizing the system layout in order to reduce power drawn by system. The present paper evaluates the improvement of cabin comfort and reduce the energy consumption of an electric car AC system by optimizing the layout and position of condenser and compressor. The experiments were

Sen, Somnath, Jadhav, Yash, Singh, Karamjeet, Sorte, Swapnil, Anwar, Md Tahir

Coordinated Motor Speed Control Design for Seating Systems

2025-01-8069To be published on 04/01/2025

Automotive seating systems have become much more sophisticated in terms of providing more flexible configurations and comfort functionalities to the consumer. Regular power seating with a few motors to move and adjust the seat position has turned to be more technical advanced reconfigurable systems with more sensors and actuators, such as Easy Entry, Zero Gravity, Stadium Swivel IP Nesting, Power Long Rails etc. The overall control of the seating becomes more and more like the robotics control with many coordinated movements. In this paper, a novel control strategy is proposed for the coordinated speed controls of multiple motors. Unlike traditional seating controls, other than the open loop controls, a feed-back approach is proposed together with a Kalman-filter based speed estimation via raw signal of Hall Effect sensor. The control of multiple motors at the same time will also be coordinated and synchronized properly, so that the seat will move in coordination, will not only not to

Yang, Hanlong, Li, Miranda

Evaluating the Impact of Sensor Accuracy on Adaptive Cruise Control Performance: A Simulation Study

2025-01-8063To be published on 04/01/2025

Adaptive Cruise Control (ACC) is an advanced driver assistance system that manages a vehicle's longitudinal motion. Its performance heavily depends on the accuracy of the sensors used. While ACC algorithms are designed to optimize performance, the effectiveness of the ACC system is significantly influenced by sensor accuracy and performance. Although the key performance indicator (KPI) of the ACC system is crucial for evaluating its effectiveness, quantifying the exact impact of sensor accuracy on this KPI presents challenges. This paper investigates the effect of sensor accuracy on ACC performance. We conducted a simulation study to replicate the sensor accuracy observed in actual vehicles and analyze its impact on ACC performance. Additionally, the paper explores potential solutions to mitigate performance variations caused by sensor accuracy variability

Awathe, Arpit, Varunjikar, Tejas, Raut, Abhinandan Vijay, Patel, Darsh

Research on Crash Simulation and Safety of Automotive Power Battery

2025-01-8226To be published on 04/01/2025

In order to analyze the safety performance of the power battery pack of a certain model and optimize it. The finite element model of the battery pack is constructed by Hyperworks software, and then the pre-processing of the finite element model is carried out, which includes the simplification of the model, mesh partitioning, parameter selection and so on. The processed model is used to simulate and analyze the mechanical impact, random vibration, and side rigid column collision of the battery pack, and explore the specific situation of the damage of the power battery pack. Under the current GB, in combination with E-NCAP, a simulation program is provided for the battery pack to be subjected to side rigid column collision. In order to reduce the mass of the automotive power battery pack under certain working conditions, parametric modeling of its components and parameter optimization combined with multi-objective genetic algorithms are carried out, and the results show that the mass of

Wang, Zhi

Advanced Methodology for Accelerated Durability Block Cycle Testing of Automotive Rubber Suspension Bushings and Powertrain Mounts

2025-01-8236To be published on 04/01/2025

In the field of automotive engineering, the performance and longevity of suspension bushings and powertrain mounts are critical. These components must endure fatigue loads characterized by their variable amplitude, multi-axial nature, and out-of-phase oscillations. The challenge lies in comprehensively characterizing these service loads during the early stages of vehicle production to foresee potential issues that may arise during later stages. Additional complexity in this analysis is introduced by the nonlinear hyperelastic deformation exhibited by natural rubber, a common material used in these components. To address these challenges, original equipment manufacturers (OEMs) and suppliers employ Computer-Aided Engineering (CAE) techniques for fatigue life predictions. These predictions are complemented by physical testing involving what are known as block cycles. However, the results obtained from these approaches often fail to fully represent the real loading conditions that a

Zarrin-Ghalami, Touhid, Datta, Sandip

Weldlife Variational Assessment for Exhaust System Using Monte Carlo Approach

2025-01-8198To be published on 04/01/2025

Different parts in Automotive exhaust assembly are joined to vehicle body through welding which is likely to develop significant stress at the weld locations when subjected to road dynamic loading. Needless to mention that design of these welds needs to robust enough not to fail during the life cycle of the vehicle for any variations in manufacturing and other parameters. This work aims to evaluate the variance of weldlife with respect to input variations in the exhaust system and compare the same with life requirements USING VIRTUAL ROAD LOADS. The variations in parameters such as parts thickness, shape, isolator stiffness and flex-coupling stiffness rates are considered. To predict the weldlife, exhaust connection weld elements are grouped as an individual set and evaluated. The variations in shape parameters are defined using morphing and interfaced to the GM proprietary process for creation of morphed geometry within the DOE variations. Bounds for these input variables are chosen

Ramamoorthy, Rajapandian, Bazzi, Ramzi

Modelling of Vehicle Efficiency Through Thermal System Plant and Controls Integration

2025-01-8186To be published on 04/01/2025

Improving the efficiency of Battery Electric Vehicles (BEVs) is crucial for enhancing their range and performance. This paper explores the use of virtual tools to integrate and optimise various systems, with a particular focus on thermal management. The study considers global legislative drive cycles and real-world scenarios, including hot and cold weather conditions, charging cycles, and towing. A virtual vehicle model is developed to include major contributors to range prediction and optimization, such as thermal systems. Key components analysed include high voltage (HV) and low voltage (LV) consumers (compressors, pumps, fans), thermal system performance and behaviour (including cabin climate control), thermal controllers, and thermal plant models. The emergent behaviour resulting from the interaction between hardware and control systems is also examined. The methodology involves co-simulation of hardware and control models, encompassing thermal systems (coolant, refrigerant, cabin

Tourani, Abbas, Price, Christopher, Dutta, Nilabza, Moran Ruiz, Eduardo

Enhanced Sorting Investigation of Retired Lithium-Ion Batteries Based on Electrochemical Impedance Spectroscopy

2025-01-8130To be published on 04/01/2025

Given the promising prospects of retired lithium-ion batteries in second-life utilization, enhancing their consistency through a rational sorting process has become a pressing priority. Traditional capacity-based sorting methods have significant limitations as it takes high time costs and fails to provide internal dynamic information about the batteries. To address this, the present study introduces a novel approach by incorporating electrochemical impedance spectroscopy (EIS) into the sorting process. Firstly, principal component analysis (PCA) analysis is applied to extract the first principal component from the EIS data, which has a strong correlation with battery capacity. It serves as a key feature for assessing the residual value of retired batteries. Accurate estimation of battery capacity is then achieved using a simple linear equation: For retired nickel-cobalt-manganese (NCM) batteries, the mean absolute percentage error (MAPE) and root mean squared percentage error (RMSPE

Fan, Wenjun, Wang, Xueyuan, Jin, Yiqun, Jiang, Bo, Zhu, Jiangong, Wei, Xuezhe, Dai, Haifeng

Electronic Control Unit Hardware Design Challenges for Software Defined Vehicle

2025-01-8136To be published on 04/01/2025

Software Defined Vehicle (SDV) is gaining attraction in the automotive industry due to its wide range of benefits like remote software/feature upgrade, scalable functionality, Electronic Control Unit (ECU) commonization, remote diagnostics, increased safety, etc. To obtain all these benefits, ECUs need to be designed accordingly. ECU hardware must be designed to support a range of vehicles with a variety of loading, scalable features, power distribution, levels of processing, and networking architecture. Each domain has unique challenges to make the ECU economical and robust to operating conditions without compromising performance. This paper illustrates the critical hardware design challenges to accommodate a scalable SDV architecture. This paper focuses electrical interface design to support wide range of input/output port loads, scalable functionality, and robust diagnostics. Also, flexibility of microprocessor processing capability, ECU networking, and communication complexity are

Hasan, S.M. Nayeem, Irgens, Peter

Portable Track-Based Connected Intersection Testing System for Connected and Automated Vehicles

2025-01-8062To be published on 04/01/2025

Connected and automated vehicle (CAV) technology is a rapidly growing area of research as more automakers strive towards safer and greener roads through its adoption. The addition of sensor suites and vehicle-to-everything (V2X) connectivity gives CAV enabled vehicles an edge on predicting lead vehicle and connected intersection states, allowing them to adjust trajectory and make more fuel-efficient decisions. Optimizing the energy consumption of longitudinal control strategies is a key area of research in the CAV field as a mechanism to reduce overall energy consumption of vehicles on the road. One such CAV feature is autonomous intersection navigation (AIN) with eco-approach and departure through signalized intersections using vehicle-to-infrastructure (V2I) connectivity. Much existing work on AIN has been tested using model-in-loop (MIL) simulation due to being safer and more accessible than on-vehicle options. To fully validate the functionality and performance of the feature

Hamilton, Kayla, Misra, Priyashraba, Ord, David, Goberville, Nick, Crain, Trevor, Marwadi, Shreekant

Incorporating the Scenario-Based Framework Underpinned by Operational Design Domain (ODD) for Automated Driving Stack (ADS) Evaluation

2025-01-8067To be published on 04/01/2025

The rapid development of open-source Automated Driving System (ADS) stacks has created a pressing need for clear guidance on their evaluation and selection for specific use cases. This paper introduces a scenario-based evaluation framework combined with a modular simulation framework, offering a scalable methodology for assessing and benchmarking ADS solutions, including but not limited to off-the-shelf designs. The study highlights the lack of clear Operational Design Domain (ODD) descriptions in such systems. Without a common understanding, users must rely on subjective assumptions, which hinders the process of accurate system selection. To address this gap, the study proposes adopting a standardised ISO 34503 ODD description format within the ADS stacks. The application of the proposed framework is showcased through a case study evaluating two open-source systems, Autoware and Apollo. By first defining the assumed system's ODD, then selecting a relevant scenario, and establishing

Chodowiec, Emil, Zhang, Xizhe, Mitchell, Joe, Baker, Peter, Khastgir, Siddartha, Jennings, Paul

CL-infoRRT collision-avoidance trajectory planning for autonomous vehicle

2025-01-8027To be published on 04/01/2025

To ensure the safety and stability of road traffic, autonomous vehicles must proactively avoid collisions with traffic participants when driving on public roads. To achieve effective obstacle avoidance, this paper proposes a CL-infoRRT planning algorithm. CL-infoRRT consists of two parts. The first part is the informed RRT algorithm for structured roads, which is used to plan the reference path for obstacle avoidance. The second part is a closed-loop simulation module that incorporates vehicle kinematics to smooth the planned obstacle avoidance reference path, resulting in an executable obstacle avoidance trajectory. To verify the effectiveness of the proposed method, four test scenarios and four RRT comparison algorithms were set up. The implementation results show that all five algorithms can generate obstacle avoidance trajectories in the four scenarios. However, compared with the comparison algorithms, the proposed method uses fewer nodes. In Scenario 1, the proposed method uses

Wu, Wei, Lu, Jun, Zeng, Dequan, Yang, Jinwen, Hu, Yiming, Yu, Qin, Wang, Xiaoliang

A Path Tracking Control Method Considering Vehicle Stability and Road Curvature

2025-01-8038To be published on 04/01/2025

The current research on path tracking control focuses on the improvement of tracking accuracy, while ignoring the comfort of the passengers inside the vehicle. Improving comfort can be achieved by improving the algorithm in two aspects: imitating human driving behavior and considering vehicle driving stability. Therefore, this paper proposes a path tracking control method considering vehicle stability indicators and road curvature changes, with the following main content: first, vehicle dynamics modeling is performed, and its dynamics characteristics are analyzed to extract key indicators related to the enhancement of ride comfort in the driving process. This includes combining the human comfort evaluation index of whole-body vibration and the vehicle maneuverability index, and calculating the interval of the relevant vehicle dynamics indexes for the case where the passenger comfort is the highest in the vehicle driving process. Second, the path tracking controller is designed by

Lu, Jun, Zeng, Dequan, Hu, Yiming, Wang, Xiaoliang, Liu, Dengcheng, Jiang, Zhiqiang

Uncovering Security Flaws in DC Chargers for Electric Vehicles

2025-01-8118To be published on 04/01/2025

The added connectivity and transmission of personal and payment information in electric vehicle (EV) charging technology creates larger attack surfaces and incentives for malicious hackers to act. As EV charging stations are a major and direct user interface in the charging infrastructure, ensuring cybersecurity of the personal and private data transmitted to and from chargers is a key component to the overall security. Researchers at Southwest Research Institute® (SwRI®) evaluated the security of direct current fast charging (DCFC) EV supply equipment (EVSE). Identified vulnerabilities included values such as the MAC addresses of both the EV and EVSE, either sent in plaintext or encrypted with a known algorithm. These values allowed for reprogramming of non-volatile memory of power-line communication (PLC) devices as well as the EV’s parameter information block (PIB). Discovering these values allowed the researchers to access the IPv6 layer on the connection between the EV and EVSE

Kozan, Katherine

Dynamic Trust Model for Software Defined Vehicles

2025-01-8084To be published on 04/01/2025

Today's vehicle architectures build trust on a framework that is static, binary and rigid; tomorrow's software defined vehicle architectures require a trust model that is dynamic, nuanced, and adaptive. The Zero Trust paradigm supports this dynamic need, but current implementations focus on protecting information, not considering the challenges that automobiles face interacting with the physical world. We propose expanding Zero Trust for cyber-physical systems by weighing the potential safety impact of taking action based on information provided against the amount of trust in the message and develop a method to evaluate the effectiveness of this strategy. This strategy offers a potential solution to the problems of implementing real-time responses to active attacks over vehicle lifetime

Kaster, Robert, Ma, Di

Options for introducing SOVD in SDV architectures

2025-01-8081To be published on 04/01/2025

The trend for the future mobility concepts in the automotive industry is clearly moving towards autonomous driving and IoT applications in general. Today, the first vehicle manufacturers offer semi-autonomous driving up to SAE level 4. The technical capabilities and the legal requirements are under development. The introduction of data- and computation-intensive functions is changing vehicle architectures towards zonal architectures based on high-performance computers (HPC). Availability of data-connection to the backend and the above explained topics have a major impact on how to test and update such ‘software-defined’ vehicles and entire fleets. Vehicle diagnostics will become a key element for onboard test and update operations running on HPCs, as well as for providing vehicle data to the offboard backend infrastructure via Wi-Fi and 5G at the right time. The standard for Service Oriented Vehicle Diagnostics (SOVD) supports this development. It describes a programming interface for

Mayer, Julian, Bschor, Stefan, Fieth, Oliver

End-to-end Style Parking Algorithm Development Pipeline Based on Procedural Parking Scenario Synthetic Data Generation

2025-01-8060To be published on 04/01/2025

Less costs and higher efficiency may be the constant technological pursuit of engineers. Despite the great success, data-driven AI development still requires multiple stages such as data collection, curation, annotation, training, and deployment to work together. We expect an end-to-end style development process that can integrate these processes, achieving the an automatic data production and algorithm development process that can complete with just one click of the mouse. For this purpose, we explore an end-to-end style parking lot algorithm development pipeline based on procedural parking scenario synthetic data generation. Our approach allows for the automated generation of parking scenarios according to input parameters, such as scene construction, static and dynamic obstacles arrangement, material textures modification, and background changes. It then combines with the ego-vehicle trajectories into the scenarios to render high-quality images and corresponding label data based on

Li, Jian, Wang, Hanchao, Zhang, Song, Meng, Chao, rui, Zhang

Advanced Driver Assistance Systems (ADAS): Assessing the Efficacy of Non-Impact Testing for Evaluating the Performance of Frontal Collision Mitigation Technology

2025-01-8056To be published on 04/01/2025

As Automatic Emergency Braking (AEB) systems become standard equipment in light duty vehicles, the ability to evaluate these systems efficiently is becoming critical to regulatory agencies and manufacturers. One of the key drivers of the cost and time required to evaluate the performance of these systems is the potential collision between the subject vehicle and the test target. AEB performance can vary significantly between different scenarios, especially with high closing speeds. Consequently, high speed impacts that may occur while evaluating the performance of an AEB system can result in significant damage to both the subject vehicle and the test equipment, and result in significantly higher test costs. For tests in which impact with the test target is not acceptable, an alternative methodology is often used: steering is applied by the driver to avoid the target prior to a potential collision. A test series was performed to determine if this alternative evaluation methodology can

Kuykendal, Michelle, Easter, Casey, Koszegi, Giacomo, Alexander, Ross, Paradiso, Marc, Scally, Sean

Reducing Power Consumption through Effective Data Sharing in Platooning Scenarios

2025-01-8051To be published on 04/01/2025

Platooning occurs when vehicles travel closely together to benefit from multi-vehicle movement, increased road capacity, and reduced fuel consumption. This study focused on reducing energy consumption under different driving scenarios and road conditions. To quantify the energy consumption, we first consider dynamic events that can affect driving, such as braking and sudden acceleration. In our experiments, we focused on modeling and analyzing the power consumption of autonomous platoons in a simulated environment, the main goal of which was to develop a clear understanding of the different driving and road factors influencing power consumption and to highlight key parameters. The key elements that influence the energy consumption can be identified by simulating multiple driving scenarios under different road conditions. The initial findings from the simulations suggest that by efficiently utilizing the inter-vehicle distances and keeping the vehicle movements concurrent, the power

Khalid, Muhammad Zaeem, Azim PhD, Akramul, Rahman, Taufiq

Analysis of Geo-Location Data from Military Tactical Vehicles to Derive Wireless Recharging Requirements

2025-01-8341To be published on 04/01/2025

As the military community considers the use of electrified tactical vehicles, wireless power transfer has emerged as a desirable method for recharging these vehicles. This technique enables multiple vehicles to recharge while in close proximity during motor pool or patrol base operations. A mobile wireless recharging platform could be deployed to these vehicle concentrations for recharging. This study evaluates the feasibility and requirements of such a system by examining the duration that vehicles remain close enough for effective power transfer. Vehicle geo-location data from the National Training Center for an infantry brigade combat team, encompassing over 400 tactical vehicles, is used to map vehicle movements. The study involves the extraction, cleaning, and analysis of this data to identify periods when vehicles are grouped closely enough to facilitate wireless recharging. The analysis quantifies the time vehicles spend in proximity and the average distance between them to

Mittal, Vikram, El Ouadi, Ameir

SPC based Critical Parameters Monitoring of Vendor Supplied Parts by Auto OEM for Quality Control

2025-01-8334To be published on 04/01/2025

In Automobile manufacturing, maintaining the Quality of vendor-supplied parts is crucial. This paper introduces a digital tool designed to monitor critical parameters of these parts in real-time. Utilizing Statistical Process Control (SPC) graphs, the tool continuously tracks essential parts and process parameters, predicting potential issues for proactive improvements even before parts are supplied. The tool integrates data from all vendor partners into a single platform, providing a comprehensive view of their performance and the parts they supply. Vendors input data into a digital application, which is then analyzed in the cloud using SPC techniques to predict potential alerts for improvement. These alerts are automatically sent to both vendors and relevant personnel at the OEM, enabling proactive measures to address any quality deviations. 100% data is visualized in an integrated dashboard which acts as a single source of truth for all stakeholders. Real-time monitoring is done

Sahoo, Priyabrata, Garg, Ishan, Rawat, Sudhanshu, Narula, Rahul, Gupta, Ankit, Bindra, Ritesh, Rao, Akkinapalli VN, Garg, Vipin

Effects of Targeted Instruction on Non-Functional Requirement Understanding: A Case Study in Graduate Vehicle Design

2025-01-8348To be published on 04/01/2025

Comprehensive requirements generation is a critical stage of the design process. Requirements are used to bound the design space and to guide the selection and evaluation of various solutions. Requirements can be categorized as either functional, defining things that the solution must do (such as produce a certain amount of horsepower), or non-functional, defining desirable qualities of the solution (such as weigh less than a particular value). Functional requirements are relatively easy to define and are often associate with particular components or subsystems within the design. As such they can be the main focus of academic design instruction and therefore the design projects undertaken by novice designers. However, non-functional requirements (NFRs) capture important characteristics of the design solution and should not be ignored. Because of their nature, they are also difficult to assign to a particular subset of components or subsystem within the system. In this study, a group of

Sutton, Meredith, Anbuvanan, Aadithan, Castanier, Matthew P., Turner, Cameron, Kurz, Mary E.

Three-body Abrasive Wear Surface Characterization of Military Diesel Engine Piston Rings and Cylinder Bores

2025-01-8346To be published on 04/01/2025

Two 50-hr engine dynamometer tests were conducted on 12-cylinder diesel military engines with differing piston ring sets. Engine A exhibited more than double the oil consumption over engine B. An investigation was conducted to explain why the oil consumption differed by employing several posttest analytical techniques including cylinder bore geometry measurements, surface metrology, wear characterization, and chemical analysis on the piston rings and cylinder wall coatings. The 3D colormaps of cylinder bore deformation showed uneven volumetric deformation through the piston stroke instead of 2D plane deformation. It was found that the primary reason of high oil consumption was direct loss of sealing between the piston, piston ring and cylinder bore due to predominately abrasive wear, three-body abrasive wear and bore polishing. Furthermore, the compromised sealing of the combustion chamber led to blow-by. Carbon deposits, corrosive byproducts, surface abrasives, loss of desired surface

Thrush, Steven, Chen, Aijie, Foley, Michael, Sebeck, Katherine, Boufakhreddine, Ziad

Data-driven Modeling and Control for Multi-Fuel Compression Ignition Engine

2025-01-8349To be published on 04/01/2025

Controlling the combustion phasing of a multi-fuel compression ignition engine in varying ambient conditions, such as low temperature and pressure, is a challenging problem. Traditionally, engine control is achieved by performing experiments on the engine and building calibration maps. As the number of operating conditions increase, this becomes an arduous task, and model-based controllers have been used to overcome this challenge. While high-fidelity models accurately describe the combustion characteristics of an engine, their complexity limits their direct use for controller development. In recent years, data-driven models have gained a lot of attention due to the available computation power and ease of model development. The accuracy of the developed models, which in turn, dictates the controller's performance, depends on the dataset used for building them. Several actuators are required to achieve reliable combustion across different operating conditions, and obtaining extensive

Govind Raju, Sathya Aswath, Sun, Zongxuan, Kim, Kenneth, Kweon, Chol-Bum

Containerization enhanced systems integration for robotics code development and deployment

2025-01-8345To be published on 04/01/2025

Over the decades, robotics deployments have leveraging synergies with rapid in-parallel research and developmental advances in sensing, actuation, simulation, algorithmic control, communication, and high-performance computing among others. Collectively, their integration within a cyber-physical-systems framework has supercharged the increasingly complex realization of the real-time ‘sense-think-act’ robotics paradigm. Successful functioning of modern-day robots relies on seamless integration of increasingly complex systems (coming together at the component-, subsystem-, system- and system-of-system levels) as well as their systematic treatment throughout the life-cycle (from cradle to grave). As a consequence, ‘dependency management’ between the physical/algorithmic inter-dependencies of the multiple system elements is crucial for enabling synergistic (or managing adversarial) outcomes. Furthermore, the steep learning curve for customizing the technology for platform specific

Varpe, Harshal Babsaheb, Coleman, John, Salvi, Ameya, Smereka, Jonathon, Brudnak, Mark, Gorsich, David, Krovi, Venkat N

A Steering Control Method Applicable to an Eight-Wheeled Planetary Laboratory

2025-01-8305To be published on 04/01/2025

In the future planet exploration mission, the eight-wheeled Planetary Mobile Laboratory (PML) has enough carrying and driving capacity to meet the needs of the mission, but it is prone to serious lateral slip during high-speed steering due to large inertia. Modern technology has made it possible to realize eight-wheel independent steering of a four-axle vehicle, but to make the whole vehicle more stable in the steering process, it is necessary to effectively control the steering angle of each wheel. To reduce the lateral offset of the eight-wheeled PML during steering, this paper proposes a novel rear axle steering feed-forward controller. First, a mathematical model of the steering control of the four-axle vehicle is established. The kinematic equations of Ackermann steering for the whole vehicle are derived, and based on this, the equations of feed-forward zero side-slip steering control for the third and fourth axes are derived. Then, a zero-slip steering control strategy is

Liu, Jun, Zhang, Kaidi, Shi, Junwei, Yang, Wenmiao, Zhang, Yunqing, Wu, Jinglai

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