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Development of the New 2.0L In-Line 4 NA Gasoline Direct Injenction Engine

2025-01-8395To be published on 04/01/2025

In recent years, from the viewpoint of climate change prevention and environmental protection, fuel efficiency and exhaust gas regulations in each country have become increasingly stringent year by year.　The share of electric vehicle and hybrid vehicle are expanding, especially in developed countries.　However, the sales ratio of gasoline vehicle is still high in the global automobile market. Therefore, it is very important to improve the environmental performance of gasoline engines from the viewpoint of environmental protection on a global scale.　Then, Honda has developed a new engine for gasoline vehicles with enhanced fuel economy and emissions performance. The newly developed gasoline engine makes maximum use of the structure and components of a gasoline engine for hybrid vehicles with excellent environmental performance that was developed in advance. As a result, in a short development period, the newly developed gasoline engine realized high environmental performance with low

Kondo, Takashi, Ohmori, Takeyuki, Yamamoto, Junpei, Miki, Kentaro

Evaluating Consumer-Grade Technology for Accident Reconstruction: A Study of Recon3D, Luma AI, and Leica RTC360

2025-01-8689To be published on 04/01/2025

This research paper investigates the effectiveness of various tools for generating 3D point clouds in accident reconstruction. Specifically, it compares the Recon3D app on the iPhone 14 and 15 Pro Max, Luma AI’s capability of generating 3D point clouds from 360-degree vehicle videos, and the industry-standard Leica RTC360 laser scanner. The study aims to capture detailed spatial data of vehicles involved in accidents, assessing the accuracy, efficiency, and usability of these tools. Controlled experiments were conducted to evaluate the performance of each tool, comparing the generated 3D models to those produced by the Leica RTC360 laser scanner. This comparative analysis highlights the potential for consumer-grade and AI-powered technologies to democratize access to advanced accident reconstruction tools, providing significant benefits to law enforcement, insurance investigators, and accident analysts

Desai, Elvis, Stemrich, Robert

High-Speed FCW & AEB Testing of Tesla Model 3's Across Software Updates

2025-01-8695To be published on 04/01/2025

A total of 148 tests were conducted to evaluate the Forward Collision Warning (FCW) and Automatic Emergency Braking (AEB) systems in five different Tesla Model 3 vehicles between model years 2018 and 2020 across four years. These tests involved stationary targets, including a foam Stationary Vehicle Target (SVT), a Deformable Stationary Vehicle Target (DSVT), a live vehicle with brake lights, and a SoftCar360 designed for high-speed impact tests. The evaluations were conducted at speeds of 35, 50, 60, 65, 70, 75, and 80 miles per hour (mph) during both daytime and nighttime conditions and utilized early and medium FCW settings. These settings, integral to Tesla's Collision Avoidance Assist, modify object detection and timing of visual and auditory warnings issued to drivers. The 2018 to 2020 vehicles initially utilized both cameras and radar for object detection. Tesla updated their software and detection algorithm, and thus, vision-only tests were able to be conducted as a comparison

Harrington, Shawn, Nagarajan, Sundar Raman

An Introduction to the Forensic Acquisition and Analysis of Mobile Device Data for Accident Reconstruction

2025-01-8706To be published on 04/01/2025

Mobile devices have become ubiquitous in modern society, and the data they store has become increasingly valuable in the field of accident reconstruction. Today's mobile devices continuously capture data about our behaviors and interactions. This paper delves into the methods of acquiring data from mobile devices, such as smartphones, and examines how this data can be utilized to reconstruct vehicular accidents, particularly those involving distracted driving. The types of data that can be extracted, including call logs, text messages, app usage history, device activity, and location data, are explored in detail. Finally, a case study is presented in which various device events are examined and location data acquired from a mobile device is compared to independent Global Positioning System (GPS) instrumentation to analyze the accuracy of the retrieved data

Burgess, Shanon, Phy, Lance, Levan, Matthew

An Overview and Testing of Pedal Misapplication Systems

2025-01-8705To be published on 04/01/2025

Testing was conducted to evaluate the performance of Pedal Misapplication systems in five different vehicles in a simulated collision scenario. A 2023 BMW iX, 2023 Subaru Ascent, 2020 Tesla Model 3, 2020 Subaru Outback, and a 2014 Subaru Forester were tested in a simulated pedal misapplication scenario, whereby the test vehicle's accelerator was quickly depressed to 100% with a stationary pedestrian and vehicle target in front of the test vehicle. The testing involved measuring the performance of the respective vehicles' pedal misapplication systems, including when or if the throttle was cut, whether a forward collision warning was provided, or if the vehicle automatically braked to a stop. Results of the five vehicles tested will be presented and compared

Harrington, Shawn, Takbhate, Shubham Ramraja, Martin, Nicholas, Handzic, Dino, Patrick-Moline, Peyton

Predicting Head Injury Criterion in Real-World Frontal Impacts

2025-01-8709To be published on 04/01/2025

Research on modeling head injury metrics and head acceleration waveforms from real-world collisions has been limited compared to vehicle crash pulses. Prior studies have used simple pulse functions to model vehicle crash pulses and have employed more complex approximations for head injury metrics. This study aimed to develop a method to predict 15 ms Head Injury Criterion (HIC15) in frontal passenger vehicle impacts using simple pulse functions, where only occupant peak head acceleration and head impact duration are known. Vehicle crash tests from the New Car Assessment Program (NCAP) were selected for frontal impacts that include driver occupants, then separated for training and testing. The resultant head acceleration-time curves of the driver Hybrid III 50th percentile male anthropomorphic test devices were collected. Rectangular, triangular, quadratic, half-sine, and half-haversine pulse functions were modeled using peak head acceleration and the duration of significant head

Westrom, Clyde, Tanczos, Rachel, Adanty, Kevin, Shimada, Sean

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, Champhekar, Omkar, Gurunadhan, Mohana, Konangi, Santosh, haghnegahdar, Ahmad

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

2025-01-8148To be published on 04/01/2025

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

Real-time PMV Thermal Comfort Index Observer based on Artificial Neural Networks for Infrared Heating Panels Control

2025-01-8139To be published on 04/01/2025

Improving electric vehicles’ range can be achieved by integrating infrared heating panels (IHPs) into the existing Heating Ventilation and Air-Conditioning system to reduce battery energy consumption while maintaining thermal comfort. Localized comfort control enabled by IHPs is facilitated by thermal comfort index feedback to the control strategy, such as the well-known Predicted Mean Vote (PMV). PMV is obtained by solving nonlinear equations iteratively, which is computationally expensive for vehicle control units and may not be feasible for real-time control. This paper presents the design of real-time capable thermal comfort observer based on feedforward artificial neural network (ANN), utilized for estimating the local PMV extended with IHP radiative heating effects. The vehicle under consideration is equipped with 12 heating panels (zones) organized into six controller clusters that rely on the average PMV feedback from its respective zone provided by a dedicated ANN. Each of six

Cvok, Ivan, Yerramilli-Rao, Isha, Miklauzic, Filip

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 focuses on the optimization of 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 modelling and analyzing the power consumption of autonomous platoons in a simulated environment. The main goal of experiments in a simulated environment is to develop a clear understanding of the different driving and road factors influencing power consumption and to identify optimization parameters. By simulating multiple driving scenarios under different road conditions, the key elements that influence energy consumption can be identified. The initial findings from the simulations suggest that by optimizing the inter- vehicle distances and keeping the

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

The Rain Test Domain: An Outdoor Testbed for Automotive Sensor Evaluation in Adverse Weather Conditions

2025-01-8058To be published on 04/01/2025

The rapid development of autonomous vehicles necessitates rigorous testing under diverse environmental conditions to ensure their reliability and safety. One of the most challenging scenarios for both human and machine vision is navigating through rain. This study introduces the Digitrans Rain Testbed, an innovative outdoor rain facility specifically designed to test and evaluate automotive sensors under realistic and controlled rain conditions. The rain testbed features a wetted area of 600 square meters and a rain volume of 600 cubic meters, providing a comprehensive environment to rigorously assess the performance of autonomous vehicle sensors. Rain poses a significant challenge due to the complex interaction of light with raindrops, leading to phenomena such as scattering, absorption, and reflection, which can severely impair sensor performance. Our facility replicates various rain intensities and conditions, enabling comprehensive testing of radar, lidar, and camera sensors. By

Feichtinger, Christoph Simon

Operational Evaluation of a Pre-Production L2 System HMI

2025-01-8050To be published on 04/01/2025

The study analyzed data from naturalistic, on-road drives of a pre-production Level 2 (L2) partial automation system using a sample of 27 drivers ranging from 21 to 75 years of age. This system provides continuous automatic lateral and longitudinal control but requires the driver to remain attentive and intervene when necessary. The L2 system was equipped with a Driving Monitoring System (DMS) that issued escalating alerts to remind the driver to pay attention or take over when needed. During the 14-month study period, drivers completed 354,768 miles of travel with the L2 system engaged, totaling 5,913 trips. The results of the study showed that drivers were highly responsive to attention reminders and takeover alerts, with high compliance rates and quick response times. Importantly, there was no evidence of habituation to these alerts over time. These findings support the effectiveness of the system's DMS and alert HMI (Human-Machine Interface) strategy in promoting the proper use of

Llaneras, Robert, Glaser, Yi, Landry, Steven, Kiefer, Raymond, Green, Charles

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

Effect of Aftermarket Modifications on ADAS Functionality - 2021 Ford F-150 Light Vehicle

2025-01-8057To be published on 04/01/2025

Both the automotive aftermarket and Advanced Driver Assistance Systems (ADAS) are growing. However, there is very little information available in the public domain about the effect of aftermarket modifications on ADAS functionality. To address this deficiency, a research study was previously performed in which a 2022 Chevrolet Silverado 1500 light truck was tested in four different hardware configurations. These included stock as well as three typical aftermarket configurations comprised of increased tire diameters, a level kit, and two different lift kits. Physical tests were carried out to investigate ADAS performance of lane keeping, crash imminent braking, traffic jam assist, blind spot detection, and rear cross traffic alert systems. The results of the Silverado study showed that the ADAS functionality of that vehicle was not significantly altered by aftermarket modifications. To determine if the results of the Silverado study were significant only for that particular light truck

Bastiaan, Jennifer, Muller, Mike, Morales, Luis

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

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

Control Trajectory Optimization of Electric Vehicle Heat Pump-based Cabin Heating System

2025-01-8144To be published on 04/01/2025

Optimal control of battery electric vehicle thermal management systems is essential for maximizing the driving range in extreme weather conditions. Vehicles equipped with advanced heating, ventilation and air-conditioning (HVAC) systems based on heat pumps with secondary coolant loops are more challenging to control due to actuator redundancy and increased thermal inertia. This paper presents the dynamic programming (DP)-based offline control trajectory optimization of heat pump-based HVAC aimed at maximizing thermal comfort and energy efficiency. Besides deriving benchmark results, the goal of trajectory optimization is to gain insights for practical hierarchical control strategy modifications to further improve real-time controllers’ performance. DP optimizes cabin inlet air temperature and flow rate to set the trade-off between thermal comfort and energy efficiency while considering the nonlinear dynamics and operating limits of HVAC system in addition to typically considered cabin

Cvok, Ivan, Deur, Josko

The Effect of Rotor Notches on Air Gap Heat Transfer Coefficient and Electromagnetic Performance in a Traction Permanent Magnet Synchronous Motor

2025-01-8143To be published on 04/01/2025

This study investigates the impact of various notch geometries, specifically on the outer surface of the rotor of a permanent magnet synchronous motor, on the thermal and electromagnetic (EM) performance. Typical motor cooling methods, such as water jackets or oil spray/impingement, usually target the stator and/or end windings, relying on heat transfer through the airgap to cool the rotor, even though air acts as an insulator. Rotor notches are often used to reduce cogging torque and torque ripple by improving the quality of air gap flux density distribution, leading to a significant increase in motor efficiency and overall performance. The effect of rotor notches on EM performance is well understood, but its impact on the thermal management of the motor, particularly the heat transfer coefficient (HTC) in the airgap, remains unexplored. While existing experimental and analytical work has focused on heat transfer in the airgap for smooth stator and rotor or a slotted stator with a

Zajac, Arthur, De Silva, Buddhika, Lee, Sun, Mistry, Jigar, Nasirizarandi, Reza, Jianu, Ofelia, Kar, Narayan

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

Alzu'bi, Hamzeh

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

Advancing Verification and Validation for ADAS and ADS

2025-01-8052To be published on 04/01/2025

Emerging automotive technologies like advanced driver assistance systems (ADAS) and automated driving systems (ADS) hold promise for improving safety for the traveling public; however, effective verification and validation (V&V) of these systems has proven to be challenging. Traditional testing methodologies may serve in limited cases for systems exhibiting low levels of automation, but recent studies show that these systems that have been brought to market perform poorly in practice. Further, these traditional methods do not serve for testing systems with high levels of automation where a human driver simply serves as a fallback ready user or is out of the loop altogether. New V&V methods are required to assess whether these systems can perform their intended functions in their intended operating environments, and to assess whether they can do so safely across the expansive and variable operating space. This paper presents an overview of ADAS and ADS challenges and novel approaches to

Thorn, Eric, Knisley, Veronica, Auchter, Joseph

An Adaptive Risk-Based Access Control with Trusted Execution Environment for Vehicles

2025-01-8089To be published on 04/01/2025

The rapid development of intelligent and connected vehicles is transforming them into data-rich information carriers, which generate and store vast amounts of sensitive information. However, the frequent sharing of resources within these vehicles poses substantial risks to user privacy and data security. Should sensitive resources be accessed maliciously, the consequences could be severe, leading to significant threats to the safety, property, and reputation of both drivers and passengers. To address these risks, this paper proposes an adaptive risk-based access control with Trusted Execution Environment (TEE) specifically designed for vehicles, aimed at managing and restricting access permissions based on risk assessments. Firstly, this paper designs an adaptive risk model in accordance with ISO 21434, taking into account factors such as the security levels of subjects and objects, context, and the risk history of subjects to separately quantify threats and impacts. By adjusting the

Luo, Feng, Li, Zhihao, Wang, Jiajia, Luo, Cheng

Introducing the ML FMEA: The Next Step in Machine Learning Safety

2025-01-8078To be published on 04/01/2025

Several challenges remain in deploying Machine Learning (ML) into safety critical applications. We introduce a safe machine learning approach tailored for safety-critical industries including automotive, autonomous vehicles, medical automation, industrial robotics, and aerospace. Aiming to fill a perceived gap within Artificial Intelligence and ML standards, the described approach integrates ML best practices with the proven Process Failure Mode & Effects Analysis (PFMEA) approach to create a robust ML pipeline. The solution views ML development holistically as a value-add, feedback process rather than the resulting model itself. By applying PFMEA, the approach systematically identifies, prioritizes, and mitigates risks throughout the ML development pipeline. The paper outlines each step of a typical pipeline, highlighting potential failure points and tailoring known best practices to minimize identified risks. As an additional contribution, a populated ML FMEA template is provided

Schmitt, Paul, Pennar, Krzysztof, Lopez, Jerry, Bijelic, Mario, Seifert, Heinz Bodo

Decentralized perception system with multiple viewpoints

2025-01-8097To be published on 04/01/2025

Vehicle-to-Infrastructure (V2I) cooperation has emerged as a fundamental technology to overcome the limitations of the individual ego-vehicle perception. Onboard perception is limited by the lack of information for understanding the environment, the lack of anticipation, the drop of performance due to occlusions and the physical limitations of embedded sensors. V2I perception in a cooperative manner improves the ego-vehicle perception range by receiving information from the infrastructure that has another point of view, mounted with sensors, such as camera and LiDAR. This technical paper presents a perception pipeline developed for the infrastructure, based on images with multiple viewpoints. It is designed to be scalable and has five main components: the image acquisition for the modification of camera settings and to get the pixel data, the object detection for fast and accurate detection of four wheels, two wheels and pedestrians, the data fusion module for robust fusion of the 2D

Picard, Quentin, Fadili, Maryem, Morice, Malo, Pechberti PhD, Steve

Analyzing threats & detecting trojans using formal analysis in a semiconductor IP

2025-01-8085To be published on 04/01/2025

It is a well-known fact that a substantial part of the effort in the development of a semiconductor IP goes into verification. Since the cost of incomplete or incorrect implementation increases exponentially in the later stages of semiconductor supply chain, it is critical to identify a wide range of test cases that could prove the design achieves the functional specifications, in early stages of the project. This problem is compounded for security as identifying verification scenarios for security specification and design decisions is complicated. The problem is further compounded by the fact that the third-party IPs are generally developed following standard specification of certain technologies without much knowledge of the environment or the application where its used. Such third-party IPs also carry the risk of trojans installed into them through supply chain. In this paper we discuss how threat modelling can be used to identify potential threats in the IP and derive verifications

Ashrafi, Gulam, Dunn, Chris, Roberts, Fred

Research on Segmented Latency Testing Method for In-Vehicle Real-Time Systems Based on DDS Middleware

2025-01-8083To be published on 04/01/2025

With the rapid development of intelligent connected vehicles, their open and interconnected communication characteristics necessitate the use of in-vehicle Ethernet with high bandwidth, real-time performance, and reliability. DDS is expected to become the middleware of choice for in-vehicle Ethernet communication. The Data Distribution Service (DDS), provided by the Object Management Group (OMG), is an efficient message middleware based on the publish/subscribe model. It offers high real-time performance, flexibility, reliability, and scalability, showing great potential in service-oriented in-vehicle Ethernet communication. The performance of DDS directly impacts the stable operation of vehicle systems, making accurate evaluation of DDS performance in automotive systems crucial for optimizing system design. This paper proposes a latency decomposition method based on DDS middleware, aiming to break down the overall end-to-end latency into specific delays at each processing stage

Yu, Yanhua, Luo, Feng, Ren, Yi, Hou, Yongping

Research on Noise Optimization Control based on the New Dead Zone Compensation in Dual Motor Hybrid System

2025-01-8516To be published on 04/01/2025

In a three-phase voltage source inverter, in order to prevent the direct short circuit of the upper and lower tubes of the bridge arm and ensure the normal operation of the inverter, microsecond-level dead time needs to be added when the power devices are turned on and off. However, due to the dead-time effect, slight distortion may occur in the inverter within the modulation period, and this distortion will eventually lead to harmonic components in the output current after accumulation, thereby generating torque ripple. Against the above background, implementing dead-time compensation strategies is very important. To compensate for the voltage error caused by the dead-time effect, current polarity determination is required first. Then, the dead time is compensated, thereby indirectly compensating for the voltage error caused by the dead-time effect. Regarding the dead-time compensation time, without changing the hardware, this paper proposes a solution to turn off the dead-time

Jing, Junchao, Zhang, Junzhi, Zuo, Botao, Liu, Yiqiang, Yang, Tianyu, zhu, Lulong

FEATURES OF DESIGN AND DIAGNOSTICS OF AUTOMATIC TRANSMISSIONS OF THE GM 6T FAMILY

2025-01-8506To be published on 04/01/2025

Automatic transmission (AT) is a complex hydroelectromechanical system, since it consists of hydraulic, electrical and mechanical parts. Automatic transmission of the 6T family is mainly used on cars manufactured by "UzAuto Motors", 6-speed AT family GM 6T30, 6T40, 6T45, 6T50 "Hydra-Matic". The differences between AT 6T30/6T40/6T45/6T50 are in the thickness of the output chain and in the planetary gear, in the sizes of some other units and the housing itself. But the differences are much more strongly influenced by the transmission unit settings, which select operating modes with different engines so as not to overload the most delicate parts of the automatic transmission. 6T30, 6T40, 6T45, 6T50 have the ability to manually shift gears and activate the "kickdown" mode (for quick acceleration of the car, when you sharply press the gas "all the way" it forces the automatic to lower the gear, and sometimes by two). The operation of the transmission is controlled by various electronic

Turakulov, Bakhtiyor

Research on the Change of Mind Control during Gearshift in Hybrid System

2025-01-8509To be published on 04/01/2025

This paper initially delineates the control process of driver-initiated gear changes. The gear-shifting point control module computes the new target gear based on the current updated driving state, and the gear-shifting point decision module assesses the rationality of the new target gear and conveys it to the gear-shifting timing control module. The gear-shifting timing control module selects the reasonable new stage in accordance with the current execution status and outputs the new target gear, coordinating the clutch control module and the brake control module to regulate the clutch engagement/disengagement and the switches of the two clutches. Altering the intention regarding gear changes encompasses gear replacement and variations in power type, which involve the necessary recalculation of the target speed based on the new target gear. Secondly, the conditions for the "change of mind" request in the Speed stage are stipulated, which is the stage where the input shaft speed is

Jing, Junchao, Huang, Weishan, li, Dongfei, Zuo, Botao, Liu, Yiqiang

Torque Control of Electrified Powertrains with a degree of freedom in Actuator Acceleration and Output Torque

2025-01-8585To be published on 04/01/2025

Electrified powertrains, such as the Power Splits (Electrically Variable Transmission), Range Extenders (Series Hybrids), and Electric Vehicles with Disconnect Actuators, offer degrees of freedom in input actuator acceleration and output torque, all while consuming power from the same sources. The Hybrid Supervisory Controller (HSC) must effectively balance these parameters to meet performance and drivability metrics. However, these systems can lose control or have imbalanced control over input acceleration and output torque, particularly under power constraints or during sudden high output power demands. This paper addresses the challenge of managing competing control goals by the HSC, which must balance input and output requirements. Previous solutions often prioritized one against the other, affecting actuator performance, drivability and potentially causing unintended vehicle motion. This paper introduces a controls solution to managing multiple actuators with overlapping and often

Madireddy, Krishna Chaitanya, Banuso, Abdulquadri, Patel, Nadirsh, Sha, Hangxing, Khanal, Shishir

Evaluation of Several Tesla Dashcam Angles for Model 3 and Y Via Reverse Project Photogrammetry

2025-01-8700To be published on 04/01/2025

Tesla Model 3 and Model Y vehicles come equipped with a standard dash-camera feature with the ability to record video in four directions called TeslaCam. Additional views have been known to be recorded under specific circumstances, often triggered in impacts, and available to some owners through data requests to Tesla. Prior research into TeslaCam either did not fully explore all known camera views across multiple vehicles or the metadata associated with genuine copies of TeslaCam video. Testing and analysis of real-world crashes revealed a reliable methodology to conducting photogrammetry analysis utilizing the front, rear, and side cameras found on Tesla Model 3 and Model Y vehicles, how to verify the likelihood of any copy of TeslaCam being a genuine original video discovered during the course of an investigation, and how to examine ever changing video properties as new software becomes available for the vehicles. Moving and stationary Tesla vehicles captured frames of GPS

Jorgensen, Michael, Swinford, Scott, Imada, Kevin, Farhat, Ali

Development of a camera-based perspective transform method for quantifying passenger-vehicle driver direct visibility

2025-01-8667To be published on 04/01/2025

The Insurance Institute for Highway Safety developed a camera-based perspective transformation method for measuring driver direct visibility. This data collection method captures the driver’s full vertical and 360 lateral field of view (FOV) including pillars, side mirrors, hood and door beltlines. All-around maps of the visible ground points are generated without the need for a physical grid or external curtain setup, which is ideal for field data collection. A rig with standardized eye heights is installed in the driver’s seat to take photos every 15° laterally, with a 130° vertical FOV. The driver’s eye point is measured relative to the vehicle left front corner at ground level then camera lens characteristics are used to complete a perspective transformation, allowing annotated points on the images to be projected onto a virtual ground. This method was compared to a traditional grid method to confirm accuracy, with all forward and side points varying less than 0.6 m distance

Mueller, Becky, Bragg, Haden, Bird, Teddy

Adapting the Technology Readiness Level (TRL) Framework to AV Development

2025-01-8671To be published on 04/01/2025

The technological advancements in the automotive industry have seen a significant leap with the introduction of ADS-Equipped Vehicles (AVs), with potential for enhanced safety, efficiency, and convenience. As the development of an AV transitions from the stages of conceptual design to deployment, assessing the maturity of the technology through a structured framework is crucial. This paper proposes the adaptation of the Technology Readiness Level (TRL) framework originally developed by NASA (and adopted widely in a variety of industries) to the AV industry to provide a consistent, understandable, and transparent method to describe an AV product’s state of development. The TRL framework is mated to the existing Safety Case Framework (SCF) developed in the Automated Vehicle – Test and Evaluation Process (AV-TEP) Mission, a collaboration between Science Foundation Arizona and Arizona State University. Advancing from one TRL to the next is argued through the satisfaction of requirements

Swaminathan, Sunder, Wishart, Jeffrey, Zhao, Junfeng, Russo, Brendan, Rahimi, Shujauddin

A reconfigurable backrest surface for investigating preferred seat configurations

2025-01-8611To be published on 04/01/2025

A reconfigurable experimental seat is useful for seating comfort research, and allows researchers to investigate on effects of seat parameters and to propose quantitative guidelines for improving seat comfort. Since 2017, Gustave Eiffel University has such an experimental seat which allows us to carry out parametric studies on the geometric dimensions of a seat and to understand the role of the contact force. Equipped with force and positioning sensors, all contact forces and seat position can be measured. More specifically, the seat pan surface is composed of a matrix of 52 cylinders, each adjustable in height and each equipped with a three-axis force sensor, while the backrest is composed of three supports. These cylinders make it possible to vary the contact surface and measure the distribution of contact forces. More recently, a new system with a matrix of 263 hydraulic cylinders was designed and manufactured to better study the comfort of the backrest. As for the seat pan

Wang, Xuguang, Beurier, Georges

Nationally Scalable Hydrogen Fueling Infrastructure Deployment: A Megaregion Analysis and Optimization Approach

2025-01-8608To be published on 04/01/2025

Decarbonizing regional and long-haul freight is challenging due to the limitations of battery-electric commercial vehicles and infrastructure constraints. Hydrogen fuel cell medium- and heavy-duty vehicles (MHDVs) offer a viable alternative, aligning with the decarbonization goals of the Department of Energy and commercial entities. Historically, alternative fuels like compressed natural gas (CNG) or liquefied propane gas (LPG) have faced slow adoption due to barriers like infrastructure availability. To avoid similar issues, planning and deploying zero-emission hydrogen fueling infrastructure effectively is crucial. This research develops deployment plans for affordable, accessible, and sustainable hydrogen refueling stations, supporting stakeholders in the decarbonized commercial vehicle (CV) freight system. It aims to benefit underserved and rural energy-stressed communities by improving air quality, reducing noise pollution, and enhancing energy resiliency. The research also

Sujan, Vivek, Sun, Ruixiao, Jatana, Gurneesh, Fan, Junchuan

Self-Piercing Riveting (SPR) of magnesium high pressure die casting and dissimilar materials

2025-01-8231To be published on 04/01/2025

Solid state joining processes are attractive for magnesium alloys as they can offer robust joints without the porosity issue usually associated with welding of magnesium and dissimilar materials. Among these techniques Self-Piercing Riveting (SPR) is a clean, fast and cost-effective method widely employed in automotive industry. While SPR has been proven effective for joining aluminum and steel, it has yet to be successfully adapted for magnesium alloys. The primary challenge in developing magnesium SPR technology is the cracking of the magnesium button, which occurs due to magnesium's low formability at room temperature. Researchers and engineers approached this issue with several techniques, such as pre-heating, applying rotation to rivets, using a sacrificial layer and padded SPR. However, all these methods involve employment of new equipment or introduction of extra processing steps. The aim of this work is to introduce a SPR technique which adapts current SPR machines with minimal

Tabatabaei, Yousef, Wang, Gerry, Weiler, Jonathan

Aspects for the optimization of car production regarding efficiency, availability and sustainability

2025-01-8609To be published on 04/01/2025

Nowadays, more than in the recent decades, the design process for the body in white for passenger cars is driven by efficiency. This results in the enhanced usage of large-scale cast components made of aluminum for the battery compartment, the front or rear body and other components. While automotive industry is striving towards even larger structures made with so-called “Giga Casting” challenges in the casting and supply chain processes but also maintenance and repair processes of these large structures arise. Other tasks to solve might follow from controlling local microstructures and thus strength of the parts when flow length of the molten metal increase with component size especially in relation to an increased fraction of recycling aluminum. Within the Fraunhofer-internal project “FutureCarProduction” the emphasis is directed towards understanding what drives efficiency, availability and sustainability of modern processes for the production of a body in white. Moreover, the

Bleicher, Christoph, Qaralleh, Ahmad, Lehmhus, Dirk, Haesche, Marco, Fernandes Gomes, Leonardo, Pintore, Manuel, Kleinhans, Robert, Sommer, Silke, Tlatlik, Johannes

Comparative Study of Optimization Algorithms for 6DOF Design in Electric Vehicle Powertrain Mounting Systems

2025-01-8650To be published on 04/01/2025

Optimizing engine mounting systems is a complex task that requires balancing the isolation of vehicle vibrations with the control of powertrain movement within a limited dynamic envelope. This study investigates the application of various optimization algorithms for Six Degrees of Freedom (6DOF) analysis in engine mount design, where the stochastic behavior and probabilistic characteristics of the system present additional challenges. Selecting an appropriate optimization framework is essential for achieving accurate and efficient results. Recent advancements in research have introduced several 6DOF optimization algorithms aimed at determining the optimal stiffness and location of engine mounts. The study evaluates a range of optimization methods, including SHERPA, Quadratic Programming (QP), Genetic Algorithm (GA), Particle Swarm Optimization (PSO), Non-dominated Sorting Genetic Algorithm III (NSGA-III), Nelder-Mead, Multi-Star Local, Response Surface Method (RSM), and Simulated

Hazra, Sandip, Khan, Arkadip

Vehicle interior audio system noise prediction based on inverse acoustic approach and directivity pattern

2025-01-8640To be published on 04/01/2025

Automotive audio components must meet high quality expectations with ever-decreasing development costs. Predictive methods for the performance of sound systems in view of the optimal locations of loudspeakers in a car can help to overcome this challenge. Use of simulation methods would enable this process to be brought up front and get integrated in the vehicle design process. The main objective of this work is to develop a virtual auralization model of a vehicle interior with audio system. A hybrid simulation approach, which combines both the ray based & finite element approach to predict acoustic transfer functions & auralization effects across the audible frequency range on any chosen vehicle variant. In this paper, Acoustic Vehicle Alerting System (AVAS) speaker tested in an acoustic lab is used. The surface vibration pattern over the surface of the virtual speaker is first extracted based on measured sound pressure data. The acoustic response in a free field generated by the

Baladhandapani PhD, Dhanasekar, Thaduturu, Sai Ravikiran, Du, Isaac

A Comprehensive Study of Gaussian Process-Based Multi-Objective Multi-Fidelity Modeling Techniques and its Applications to Shell and Tube Heat Exchanger Design

2025-01-8646To be published on 04/01/2025

In numerous automotive and industrial applications, efficient heat extraction is crucial to prevent system inefficiencies or catastrophic failures. The design of heat exchangers is inherently complex, involving multiple stages defined by the depth of analysis, number of design variables, and the accuracy of physical models. Designers must navigate the trade-offs between highly accurate yet computationally expensive models and less accurate but computationally cheaper alternatives. Multi-fidelity modeling offers a solution by integrating different fidelity models to deliver precise results at a reduced computational cost. In addition to managing these trade-offs, designers often face multi-objective challenges, where optimizing one aspect may lead to compromises in others. Multi-objective optimization, therefore, becomes essential in balancing these competing objectives to achieve the best overall design. In this context, Gaussian Process-based methods have gained prominence as

Chaudhari, Prathamesh, Tovar, Andres

Unleash the power of Generative Design for lightweighting and reducing carbon footprints in Automotive Engineering

2025-01-8657To be published on 04/01/2025

The automotive industry faces ongoing challenges in reducing vehicle mass and carbon emissions while ensuring structural integrity. Traditional design approaches often fail to address these issues comprehensively. This paper explores the application of generative design (GD) to optimize critical automotive components, specifically focusing on reducing mass and in turn carbon emissions. GD builds upon traditional topology optimization by employing iterative method using MELS approach to refine designs providing multiple alternative designs to choose from. MELS (Modified Extensible Lattice Sequence) specifically is used to equally spread out points in a space by minimizing clumps and empty spaces. This property of MELS makes lattice sequences an excellent space filling DOE scheme. GD leverages the design of experiments (DOE) to vary key design variables systematically to generate and consider many potential design concepts for a given problem. It also uses artificial intelligence (AI) to

Hosmath, Anjaney, Barai, Jay, Dhangar, Vinaykumar

Automatic Generation of HVAC Ducting System Designs using Topology and Shape Optimization

2025-01-8656To be published on 04/01/2025

Topology and shape optimization of a vehicle Heating, Ventilation and Air Conditioning (HVAC) system is presented in this paper. The CFD and optimization methodologies are implemented within AcuSolve™ software. The topology optimization algorithm computes the geometry, where the design domain is parameterized with a field of porosity design variables which indicates the material, fluid or solid, throughout the domain. The optimization is performed using the continuous adjoint approach by the Galerkin Least Squares solver on which the AcuSolve™ solver is based. The design is further improved by using shape optimization. To optimize the geometrical shape, a combination of smooth perturbations, in terms of so called morph shapes, are used to deform the geometrical shape in the optimization algorithm. To this end, a parameterization of the design space is done using a moderate number of design variables, each associated with a morph shape. The two optimization phases are connected by means

Papadimitriou, Dimitrios, Sandboge, Robert

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

Performance Analysis of Commercial Vehicle Engine Cooling Fan Based on Fluid-Structure Interaction Method

2025-01-8641To be published on 04/01/2025

When the cooling fan of the commercial vehicle engine is working, there is a strong fluid-structure interaction (FSI) between the airflow and the blades. If the effect of this interaction is not considered, significant errors may be caused in the prediction of fan performance. To analyze the effect of FSI on the aerodynamic and structural performance of the cooling fan, calculation models with and without considering FSI were established. The pressure and efficiency of the cooling fan were calculated using three methods:the Multiple Reference Frame (MRF) method, the Sliding Mesh method, and the bidirectional FSI method. These results were then compared with test data. Based on the FSI method, the aerodynamic and structural performance of the fan at different flow rates, rotational speeds and temperatures were calculated, and compared with results if FSI is ignored. The effect of flow rate, rotational speed and temperature on the fan performance was analyzed. The comparison and analysis

Yu, Hui, Yin, Zhihong, Ying, Runhai, Wang, Xinling, Duan, Yaolong, Shangguan, Wenbin

MDO approach for design synthesis of automotive interior components subjected to conflicting functional requirements

2025-01-8649To be published on 04/01/2025

Light weighting has been one of the focus areas in automotive design, which has assumed greater importance for electric vehicles due to sensitivity of electric range to mass of the vehicle and increased cost of the battery packs to meet range target with increasing mass of vehicle. Mass of vehicle interior components have significant impact of overall vehicle mass due to cascading effect. Hence mass of such components must be minimized during design synthesis, where multiple design configurations may be explored with tradeoffs with regard to meeting functional requirements which are often conflicting. Assist handle bracket is one of such components in vehicle which needs to meet mandatory safety requirement of FMVSS 201U that requires the bracket to be soft. At the same time, the bracket needs to have adequate stiffness and strength to meet perceived quality and durability requirements. These are conflicting requirements which are often difficult to meet using manual design iterations

R, Rajapandian, Koppaka, Vinaya

Improving Modal Frequencies in Class 5 Truck Fuel Cell Tank Structure through Topology Optimization

2025-01-8648To be published on 04/01/2025

In addition to electric vehicles (EVs), hydrogen fuel cell systems are gaining attention as energy-efficient propulsion options. However, designing fuel cell vehicles presents unique challenges, particularly in terms of storage systems for heavy hydrogen tanks. These challenges impact factors such as NVH (noise, vibration, and harshness) and safety performance. This study presents a topology optimization study for Hydrogen Energy Storage System (HESS) tank structure in Class 5 trucks, with a focus on enhancing the modal frequencies. The study considers a specific truck configuration with a HESS structure located behind the crew cab, consisting of two horizontally stacked hydrogen tanks and two tanks attached on both sides of the frame. The optimization process aimed to meet the modal targets of this hydrogen tank structure in the fore-aft (X) and lateral (Y) directions, while considering other loadcases such as a simplified representation of GST (global static torsion), simplified side

Yoo, Dong Yeon, Chavare, Sudeep, Viswanathan, Sankar, Mouyianis, Adam

Optimization Method for Powertrain Mounting Systems Based on Enhanced Genetic Algorithms

2025-01-8644To be published on 04/01/2025

A methodology for optimizing natural properties of a powertrain for an electric vehicle has been presented. A model with six-degree-of-freedom was proposed utilizing ADAMS, and the natural frequencies and energy distribution of the powertrain are estimated using the proposed model. The calculated natural frequencies and energy distribution shown that the initial design of mount stiffness does not meet requirements of natural frequency and decoupling ratio, and vibration isolation standards. To overcome the limitations of conventional optimization techniques, a non-dominated sorting genetic algorithm (NSGA) was adopted for the enhancement optimization the mounts parameters. The optimization objectives included the refinement of the decoupling rates and frequency distribution at all mounting directions. Stiffness parameters of the mounts were optimized via the NSGA. The optimized results confirmed significant improvements for powertrain natural characteristics. This study presented an

Jin, Yang, Li, Dewei, Zhao, Yang, Xiao, Lei, Guo, YiMing

Accelerating EV Motor design using MBSE approach

2025-01-8660To be published on 04/01/2025

Abstract- Model-Based Systems Engineering (MBSE) enables requirements, design, analysis, verification, and validation associated with the development of complex systems. Obtaining data for such systems is dependent on multiple stake holders and have issues related to communication, data loss, accuracy, traceability which results in time delays. This paper presents the development of new process for requirement verification by connecting System Architecture Model (SAM) with multi-fidelity, multi-disciplinary analytical models. Stakeholders can explore design alternatives at conceptual stage, validate performance, refine system models, and take better informed decisions. The use-case of connecting system requirements to engineering analysis is implemented through ANSYS ModelCenter which integrates MBSE tool CAMEO with simulation tools MotorCAD and TwinBuilder. This automated workflow translates requirements to engineering simulations, captures output and performs validations. System

Upase, Balasaheb, Shroff, Roopesh

A Comparative Study on Road Feel Strategies for Steer by Wire Based on Parameter Fitting Method and Dynamic Model Estimation Method

2025-01-8302To be published on 04/01/2025

With the continuous development of automotive intelligence, new energy vehicles are becoming more and more popular, at the same time, new energy vehicles put forward the requirements of a steering system not dependent on the engine, better control, better steering performance, so the wire control steering system, which is controlled by the line, with high precision, fast response, can provide better flexibility, stability and comfort for the car, and can well satisfy the above requirements, and has received Widely attention. As the mechanical structure of the steer-by-wire system is canceled, the road feel can not be directly transmitted to the steering wheel, and it is necessary to apply the road feel obtained according to the state of the vehicle or combined with the planning of the driving environment to the steering wheel through the road feel motor to complete the road feel simulation so that the driver can feel the feedback similar to that of the traditional steering vehicles

Li, Shang, Zheng, Hongyu, Kaku, Chuyo

Dynamic Testing and Analysis of Autocycle Vehicles for Accident Reconstruction

2025-01-8687To be published on 04/01/2025

The Autocycle is a style of vehicle that most often utilizes a reverse-tricycle design with two front wheels and a single rear wheel. Modern autocycles in the United States are often utilized in a recreational role. This work presents physical measurements of two modern autocycles for use in accident reconstruction and pursues a deeper understanding of the unique attributes and handling associated with these vehicles. Vehicles were used to measure physical properties and subjected to cornering tests presented herein, and the data is compared to that for a conventional automobile. Observations on tire scuff marks are made from cornering tests unique to these vehicles. Strengths and challenges with this type of vehicle design are presented for various use cases as compared to conventional automobiles. Data and knowledge from this study will aid accident reconstruction efforts and act as a stepping stone for future work

Warner, Wyatt, Swensen, Grant, Warner, Mark

Road Feel Simulation Feedback in a Bi-Directional Controlled Steer-by-Wire Front Steering System for Automobiles

2025-01-8297To be published on 04/01/2025

This study analyzes feedback and control methods for road feel simulation in automotive steer-by-wire front steering systems based on bidirectional control. Unlike traditional road feel design methods, this research employs a force direct feedback-position type bidirectional control structure for the SBW system. It explores the mechanism of road feel generation in Electric Power Steering systems and designs a road feel simulation algorithm based on bidirectional control. Compared to conventional methods, the force direct feedback-position type bidirectional control method enables faster and more stable simulation of road feel torque. In low-speed driving, this approach provides higher steering ease, while at high speeds, the driving stability is enhanced, and both scenarios achieve improved road feel. In the research, a complete vehicle model is established in Simulink at first, followed by a co-simulation with CarSim. A magic formula tire model and a nonlinear two-degree-of-freedom

Wang, Yuxuan, Zheng, Hongyu, Kaku, Chuyo, Zong, Changfu

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