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Innovative High-Performance Active Dampers for Effective Mitigation of Helicopter Main Rotor Vibrations

2025-01-0163To be published on 04/25/2025

Helicopter vibrations, primarily generated by the main rotor-gearbox assembly, are a major source of concern due to their impact on structural integrity, cockpit instrument durability, and crew comfort. These vibrations are mainly transmitted through the gearbox’s rigid support struts to the fuselage, leading to increased cabin noise and potential damage to critical components. This paper presents a solution for vibration mitigation which involves replacing traditional gearbox support struts with low-weight, high-performance active dampers. Developed by Elettronica Aster S.p.A., these active dampers are designed as electro-hydraulic actuators embedded within a compliant structure. The parallel nested configuration of the system enables high power densities and effective vibration control, significantly reducing the transmission of harmful vibrations to the fuselage. The comprehensive model-based design process is detailed, describing the development and use of a high-fidelity physics

Bertolino, Antonio Carlo, Sorli, Massimo, Porro, Paolo Giovanni, Galli, Claudio

Enhancing Efficiency in Aerospace Manufacturing through AI Agent Based Bearing Diagnostics System

2025-01-0158To be published on 04/25/2025

Industrial bearings are critical components in aerospace manufacturing, where their failures can result in costly downtime. Traditional fault diagnosis typically depends on time-consuming on-site inspections conducted by specialized engineers. This research introduces an innovative Artificial Intelligence application that functions as a virtual maintenance technician, empowering on-site personnel to perform preliminary diagnoses. By reducing the dependence on specialized engineers, this technology aims to minimize downtime. The AI system leverages large language models to guide the inspection process, answer queries from a comprehensive knowledge base, analyze defect images, and generate detailed reports with actionable recommendations. Multiple deep learning algorithms operate as backend APIs to support this functionality. This study details the architectural design of the expert system and provides a real-time simulation of its workflow, demonstrating its potential to enhance

CHANDRASEKARAN, BALAJI

Empirical Inflow Ratio Adjustment for Hovering Open Rotors with Experimental Validation

2025-01-0162To be published on 04/25/2025

This study presents empirical modifications of Blade Element Momentum Theory (BEMT) to improve rotor performance prediction for open rotors in hovering conditions. The empirical adjustments were made to the inflow ratio, factoring in the real rotor wake area and estimated induced power losses. A comparison between experimental data and two analytical models, one using an empirical inflow formula and the other a theoretical formula (classical BEMT), was conducted for two rotors. The empirical inflow model demonstrated superior accuracy in predicting thrust and torque. These modifications are applied to the inflow ratio by accounting for the actual rotor wake area and estimated induced power losses. The findings highlight the potential for more accurate performance prediction through the integration of empirical data into theoretical frameworks.

Dayhoum, Abdallah, Ramirez-Serrano, Alejandro, Martinuzzi, Robert

Interconnected and Data-Driven Aircraft Cabin Systems: Consistent Integration of ARINC 853 Messaging Standard into Model-Based Aircraft Systems Development

2025-01-0174To be published on 04/25/2025

Increasing digitalization of the aircraft cabin, driven by the need for improved operational efficiency and an enhanced passenger experience, has led to the development of data-driven services. In order to implement these services, information from different systems is often required, which leads to a multi-system architecture. When designing a network that interconnects these systems, it is important to consider the heterogeneous device and supplier landscape as well as variations in the network architecture resulting from airline customization or cabin upgrades. The novel ARINC 853 Cabin Secure Media-Independent Messaging (CSMIM) standard addresses this challenge by specifying a communication protocol that relies on a data model to encode provided and consumed information. This paper presents an approach to integrate CSMIM-specific communication concepts into a Model-Based Systems Engineering (MBSE) framework using the Systems Modeling Language (SysML). This enables a streamlined

Giertzsch, Fabian, Blecken, Marvin, God, Ralf

Drilling Methods for Controlling Exit Burr Height in CRES Material Stacks

2025-01-0169To be published on 04/25/2025

The Electroimpact Automatic Fan Cowl Riveter uses two novel drill processes to control exit burr height and achieve the required hole quality in CRES (Corrosion-Resistant Steel, also called stainless steel) material stacks. Both processes use piloted cutters on the OML side, and two different tools are used in a backside spindle on the IML side of the component. The first process uses a shallow-angle shave tool in the IML spindle to directly control the exit burr height after it is produced by the OML spindle and is called the “burr shave” technique. The second process uses a countersink tool in the IML spindle and produces an “intermediate countersink” after the pilot hole is drilled by the OML spindle, but before the final hole diameter is drilled. These drill processes were able to achieve the required hole quality in a challenging CRES material stack, which allows the machine to be qualified for one-up assembly of the component.

Schultz, Rich, Peterman, Randy, Luker, Zachary, Murakonda, Sai Krishna

Comparison of Different Joining Techniques as a Benchmark for Integrally Joined Thermoformed Components Based on Tailored rCF Organosheets

2025-01-0170To be published on 04/25/2025

Climate-neutral aviation requires resource-efficient composite manufacturing technologies and viable solutions for the reuse of carbon fibers (CF). In this context, thermoplastic composites (TPC) can make a strong contribution. Thermoforming of TPC is an efficient and established process for aerospace components. But it’s efficiency could be further increased by integration of joining processes, which would otherwise be separate steps. In this work, a two-step thermoforming process for hollow box structures, particularly uplift structures, is presented. The starting point are two organosheets. First, one of the organosheets, intended for the bottom skin of the uplift structure, is thermoformed. After cooling, the press opens, the organosheet remains in the press and an infrared heater is pivoted in, to locally heat up just the joining area. Meanwhile, a second organosheet, intended for the top skin, is heated and thermoformed and simultaneously joined to the lower skin, thereby forming

Vocke, Richard, Seeßelberg, Lorenz, Focke, Oliver, Dietrich, Jan Yorrick, Jobke, Katrin, Albe, Christopher, May, David

More Electric Engine Technologies Towards the 2040s

2025-01-0152To be published on 04/25/2025

Improvement and evolution of all aircraft technologies and the commercialization of new technologies are essential to the carbon-net-zero goal of air mobility. Passenger aircraft are required to provide the ultimate in comfort, economy, and safety, and gas turbine engines will not disappear, while promoting the conversion to SAF and hydrogen fuels. The More Electric Engine (or MEE) concept, which has been proposed since the late 2000s, is one alternative. This paper focuses on the electrification of engine accessories. When the concept of electrification of engine accessories was first presented at Aerotech 10 years ago, the discussion at Aerotech seemed to be negative. Attaching a motor to conventional engine accessories would obviously increase the weight. Next, the conventional engine accessories are centrally controlled and only FADEC is in command, but electrification of engine accessories will increase the cost by adding intelligence to all the accessories. On a more academic

Umeki, Yasuyoshi, Oyori, Hitoshi, Muraoka, Mikio, Suzuki, Tsunehisa, Ogami, Yasuhiro, Yamamoto, Yasuhiko

Designing and Controlling a Hybrid Fuel Cell System for Propelling a Turboprop Aircraft

2025-01-0151To be published on 04/25/2025

In the context of aviation sector decarbonization, fuel cell hybrid electric aircrafts are a promising alternative to conventional fuels, presenting opportunities for more sustainable and efficient flight. Hence, the present work is focused on an alternative powertrain architecture, wherein a proton exchange membrane fuel cell system cooperates with a lithium-ion battery to fulfill the electrical power demand of a turboprop-based aircraft. Particularly, a mathematical tool is proposed to evaluate both the components size and performance, while a degradation aware rule-based control strategy guarantees an effective power split between the hybridizing components. Such an energy management approach introduces an idling level and a rate limiter to mitigate degradation associated with start-up/shut-down and transient phases, respectively. Moreover, to have a reliable estimation of the vehicle’s fuel economy, while also guaranteeing the correct components dimensioning, the fuel cell system

De Donato, Angelo, Aliberti, Paolo, Sorrentino, Marco, Cuomo, Fabrizio, Musto, Carmine

Machine Learning-Based Vision Mapping and Planning for Flexibility in High-Mix Robotic Manufacturing

2025-01-0157To be published on 04/25/2025

Industries that require high-accuracy automation in the creation of high-mix/low-volume parts, such as aerospace, often face cost constraints with traditional robotics and machine tools due to the need for many pre-programmed tool paths, dedicated part fixtures, and rigid production flow. This paper presents a new machine learning (ML) based vision mapping and planning technique, created to enhance flexibility and efficiency in robotic operations, while reducing overall costs. The system is capable of mapping discrete process targets in the robot work envelope that the ML algorithms have been trained to identify, without requiring knowledge of the overall assembly. Using a 2D camera, images are taken from multiple robot positions across the work area and are used in the ML algorithm to detect, identify, and predict the 6D pose of each target. The algorithm uses the poses and target identifications to automatically develop a part program with efficient tool paths, including

Langan, Daniel, Hall, Michael, Goldberg, Emily, Schrandt, Sasha

Assignment Criteria Proposal for Function Allocation to Security Domains of Aviation Systems

2025-01-0156To be published on 04/25/2025

Aircraft cabin management is characterized by operational and business processes. Both are defined as a logical sequence of activities that occur during the flight. While the operational process includes activities to ensure flight safety, such as take-off, cruise and landing, the business process activities are related to adding value to the customer, i.e. the passenger. They are to be certified by the authority as a part of the aircraft type certification. These processes are defined by the airline and are described as part of the airline’s business model. While the scope of operational processes for passenger safety within the aircraft cabin should remain as unchanged as possible, the increasing competitive pressure on airlines is leading to a constantly rising number of services in the cabin. To prevent compromising cabin safety from increased cabin crew workload during the cruise phase, there is a growing trend toward digitizing operational and business processes. The digitized

Hintze, Hartmut, Blecken, Marvin, God, Ralf, Pereira, Daniel

Material Adapted Method for the Repair of Curved Thermoplastic Composite Structures by Induction Welding of Patches

2025-01-0165To be published on 04/25/2025

Thermoplastic fiber-reinforced polymer composites (TPCs) are gaining importance in aviation due to their high strength, stiffness, and recyclability. To maximize their potential, efficient repair methods are needed to maintain aircraft safety and structural integrity. This article introduces a novel repair technique for damaged TPC structures, involving the insertion of a repair patch with a susceptor material. The susceptor consists of a material with high electrical conductivity and magnetic permeability and therefore reacts stronger to the electromagnetic field than the composite, even if it is carbon fiber based. This means that the thermal energy is specifically concentrated in the repair area. The susceptor can be placed on the patch surface or in the welding zone. The process begins by identifying and preparing the damaged area, followed by precise scarfing. Care is taken to ensure that the surrounding material remains intact and that an exact stepped structure is created, which

Geiger, Markus, Glaap, Anton, May, David, Schiebel, Patrick

Integrating for Safety – A Proposed Approach to the Integration of Propulsion Battery Systems in Hybrid Electric Aviation

2025-01-0148To be published on 04/25/2025

In the last year we have witnessed a notable surge in the designs and in the guidance material for electric and hybrid aircraft. FAA and EASA have continued to evaluate the safety of Propulsion Battery Systems (PBS), with a focus on thermal runaway containment testing. As a result, a harmonization white paper was issued to provide a certification path for Thermal Runaway (TR) Hazards, followed by an EASA certification memorandum on the acceptable approaches for the certification of Electric/Hybrid Propulsion Systems (EHPS). And just recently, an FAA Advisory Circular (draft) was issued for the “powered-lift” aircraft that feature these propulsion battery systems. In spite of the advances made by electric/hybrid aircraft manufacturers and the aviation authorities, there is still a missing piece of the puzzle. Mainly, we are still not confident in our ability to properly integrate the PBS into the EHPS architecture, in such a way where safety is never compromised, no matter the hazard

Hanna, Michael, Walker, Cherizar

Powering the Future of Sustainable Flight

2025-01-0147To be published on 04/25/2025

Eaton Aerospace is collaborating with original equipment manufacturers (OEMs) on the advancement of technologies to increase aircraft efficiency, enable aircraft electrification, and reduce carbon emissions. Leveraging our expertise as an intelligent power management company, Eaton’s products and research include hydraulic power packs, electromechanical actuation (EMA), thermal management systems, and sustainable aviation fuel (SAF). Eaton Blended Power TM systems improve efficiency through eliminating all centralized hydraulic circuits with distributed power that is provided by a combination of hydraulic power packs and EMA for a More Electric Aircraft (MEA). EMA systems, including electrical synchronization, eliminate the usage of hydraulics and provide additional functionality that benefits the flight efficiency of the aircraft. With MEA comes higher energy and thermal densities, resulting in the need for advanced thermal management. Eaton’s scalable and modular thermal management

Skinner, Jeff, Proul, Margaret, Devan, Stephen, Clendenin, Laura, Hutchinson, Lewis, Masson, Andrew, May, Frank, Momotiuk, Andy, Zuzelski, Chris

Integration of an Automated Statistical Process Acceptance (SPA) System into Automated Manufacturing to Optimize Automation Inspection Through-put, Costs, and Quality.

2025-01-0166To be published on 04/25/2025

Abstract Within the aviation industry there are increasing automation applications in concert with technology development. Automation processes by the nature of the rigid machine design have excellent accuracy and repeatability. As such, with proper utilization of the data output, the data can be used to demonstrate capability to design requirements and process control. Further the data output can be used to better address anomalies and optimize the processes. This consistency can facilitate the incorporation of inspection sampling which can significantly reduce manufacturing costs by improving product through put and labor costs. While a common heuristic is that one cannot reduce costs, and improve schedule and quality at the same time, effective use of automation and its data is an exception. However, while automation technology has developed rapidly within aviation manufacturing, industry has been less effective in 1) understanding how to set up an automated statistical control and

Hall, Thomas D.

Conceptual Design of a Superconducting Aero Electric Engine System

2025-01-0146To be published on 04/25/2025

The goal of the development of an electric aircraft engine is to create an aircraft system that achieves ultimate efficiency using hydrogen fuel instead of fossil fuels. Therefore, it is necessary to focus on reducing weight as much as possible, and this paper describes the approach to such fuel cell-powered aircraft. The authors have adopted a superconducting coreless rotating electric machine with an integrated hydrogen tank and are pursuing a target of 70kg or less for the main components of a 2MW rotating electric machine. High-temperature superconducting wires have zero electrical resistance and can carry a very high current density, but the alternating current (AC) loss generated when used in AC has been an issue in their application to rotating electric machines. In 2023, The SCSC cable was developed to be a low-AC-loss, robust, and high current cable concept, in which copper-plated multifilament coated conductors are wound spirally on a core. In addition to using this

Oyori, Hitoshi, Sakurai, Sho, Kusase, Shin, Yoshida, Yukihiro, Yoshinaga, Seiichiro, Nose, Hiroyuki, Amemiya, Naoyuki

Short-Time Current Rating of Aircraft Wire

2025-01-0145To be published on 04/25/2025

This paper presents a comparative analysis of various short-time current rating formulas, focusing on applications in aircraft wiring. Examining historical formulas developed by pioneers such as W.H. Preece and I.M. Onderdonk alongside modern experimental data provide a comprehensive understanding of short-time current rating formulas. Also, exploring key challenges, such as environmental conditions and material variability in aviation with particular attention to adiabatic methods for current-carrying calculations. The findings of this paper offer practical insights into improving the safety and reliability of an aircraft electrical system with improving the accuracy of short-time current rating predictions.

Fifield, Jon

Determining Worst-Case Execution Time Bounds for Multi-core Processors

2025-01-0155To be published on 04/25/2025

Demonstrating deadline adherence for real-time tasks is a common requirement in all safety norms, including ISO 26262 and DO-178C. Timing verification has to address two levels: the code level (worst-case execution time) and the scheduling level (worst-case response time). Determining which methodology is suited best depends on the characteristics of the target processor. All contemporary microprocessors try to maximize the instruction-level parallelism by sophisticated performance-enhancing features that make the execution time of a particular instruction dependent on the execution history. On multi-core systems, the execution time additionally is influenced by interference effects on shared resources caused by concurrent activities on the different cores, which are not controlled by the scheduling algorithm. In the avionics domain, the new FAA AC 20-193 / EASA AMC 20-193 guidance documents formalize predictability aspects of multi-core systems and derive adequate measures for timing

Kaestner, Daniel, Huembert, Christian, Gebhard, Gernot, Pister, Markus, Wegener, Simon, Ferdinand, Christian

The Why of Development Assurance

2025-01-0154To be published on 04/25/2025

In the domain of aircraft certification, Development Assurance is what some would call a useful tool to gain confidence in the development of complex systems, and what others would call a necessary evil. But what does it actually do? Why is it necessary for certification of modern aircraft? What, epistemologically, does it bring to the table? This paper aims to show why development assurance activities, at all levels from aircraft to item, close the epistemological holes created when complex systems are chosen for implementation. It will map the different sources and types of uncertainty encountered in system verification and explain how each type is dealt with within a certification context, working from simple mechanical systems up to complex and highly integrated systems using software and airborne electronic hardware and beyond. It will show that Development Assurance, far from being an arbitrary set of activities, systematically brings personal and corporate expertise to bear to

Laflin, Cory R.

Emissions and Operating Costs of Fully Electric and Hybrid-Electric for eVTOL Aircraft and the Impact of Alternative Fuels

2025-01-0149To be published on 04/25/2025

As electric aviation technologies continue to advance, the importance of understanding the benefits and drawbacks associated with power sources for electric aircraft increases. The research presented herein analyzes the emissions and operating costs of a “lift + cruise” type urban air mobility aircraft with different power sources including fully battery-electric and hybrid-electric using VerdeGo Aero’s VH-3-185 hybrid powerplant. Multiple fuels will be examined for the hybrid-electric configuration, including multiple sustainable aviation fuel (SAF) production pathways and power-to-liquid (PtL) e-SAF. The conclusions presented will show that SAF can reduce emissions by up to 87% compared to those due to the production of electric power required to recharge the fully electric aircraft. Emissions and operating costs associated with battery production are considered, including the required time of operation of a battery electric aircraft to offset the emissions due to production of its

Moeller, Piper, Roiati, Riccardo, Grantham, Dalton, Steinfeldt, Brock, Rice, Tyler

Approach to Optimize the Airplane Boarding Process by using Image Recognition and Stochastic Simulation to Predict Overhead Bin Fill Levels

2025-01-0164To be published on 04/25/2025

In single-aisle aircraft, the available storage space for carry-on baggage is inherently limited. When the aircraft is fully booked, this often results in insufficient overhead bin space, necessitating last-minute gate-checking of carry-on items, which delays the boarding process and reduces operational efficiency. A promising approach to mitigating this issue involves the integration of computer vision technologies with an appropriate data storage system and stochastic simulation to enable accurate and supportive predictions that enhance planning. In this work the YOLOv8 image recognition algorithm is used to identify and classify each passenger’s carry-on baggage into categories such as handbags, backpacks and suitcases. This data is then linked to passenger information stored in the NoSQL database MongoDB, which included seat assignments and the number of carry-on items per passenger. Stochastic simulation is applied to predict the occupancy levels of overhead storage bins across

Bergmann, Jacqueline, Hub, Maximilian

Image Processing-Based Chip Detection by KIZKI Algorithm and Its Optimization

2025-01-0168To be published on 04/25/2025

The process of producing aircraft parts involves the drilling of aluminum alloys. This creates a large amount of chips, which are removed using air, but sometimes they still remain within the holes. This is checked by inspectors through visual inspection. However, the quality of human inspection varies based on skill level and fatigue. Thus, image-based inspection should be used to stabilize and further improve inspection quality. This study aims to build a framework for chip detection based on image processing. Taking into account on-site implementation, the system must have low installation and running costs and be standalone. Therefore, we adopt the KIZKI algorithm, which satisfies these conditions. KIZKI means awareness in Japanese. This is a model of human peripheral vision and saccades. It does not require training like AI and can achieve high-speed and high-performance detection using a low-performance computer. In other words, there is no need for a computer with an expensive

Iinuma, Marin, Sato, Junya, Tsuji, Masahiko

Novel Stainless Steel Substitutes Aerospace Titanium Alloys

2025-01-0167To be published on 04/25/2025

Titanium is a critical production material for the aerospace and defense industries, and in recent years many aerospace companies have been suffering from titanium shortage in the world market. To find a long-term solution for that problem, AMD Corp. proposes a new material - Novel stainless steel - as a low-cost substitution of the high strength titanium alloys commonly used in the aerospace. The steel possesses the same or higher specific strength (a ratio of strength to density) compared to the specific strength of the commercial Ti-6Al-4V alloy at the same ductility, toughness. Corrosion resistance of Novel stainless steel approaches the corrosion resistance of 15-5PH grade. Novel stainless steel can be utilized for high-temperature (>500℃) applications, while Ti-6Al-4V alloy is limited to <500℃. Another advantage of HSCR steel is better workability and machinability compared to the Ti-6Al-4V alloy. Utilizing the Novel stainless steel offers the following benefits: • Reduces

Vartanov, Gregory

AI-Driven Design Optimization of Engineering Systems: A Case Study on Turboshaft Engines

2025-01-0173To be published on 04/25/2025

In the pursuit of optimizing complex engineering systems, the exploration and thorough understanding of the design space become imperative, particularly when dealing with multi-objective systems characterized by an array of independent variables. This paper presents a comprehensive analysis on the design space mapping of such intricate systems, utilizing a turboshaft engine as a representative case study. The initial phase of our methodology involves the employment of a physics-based model to generate a synthetic dataset. This dataset reflects the intricate interplay of various system parameters that underpin the engine's operation. The synthesized data serves as a foundation for the subsequent development of a Machine Learning or Deep Learning-based surrogate model. This surrogate AI model is meticulously crafted to encapsulate the multiple inputs and outputs inherent in the turboshaft engine's functioning, thereby facilitating an efficient and accurate exploration of the design space

PANKAJ, PEEYUSH, Thokala, Satish

MBSE Framework for Developing Data-Driven Passenger Services in Aircraft Cabins

2025-01-0171To be published on 04/25/2025

The aircraft cabin plays a crucial role in airline differentiation strategies, particularly when introducing novel business and operational processes. These processes aim to enhance passenger experience during flight and to improve cabin crew efficiency in order to reduce workload and to ensure continued growth of airline revenue. Digitalization and extensive exchange of information across the entire aircraft transport system have emerged as key enablers for these processes. The development of aircraft and aircraft systems implementing these processes is characterized by a multi-level development process. Various development levels are considered to initially identify the functions of an aircraft in the air transport system, refine its systems and break them down into their components until a level of detail is reached that allows the implementation of the component functions. In addition to the high complexity, a major challenge in this development is to ensure traceability and

Blecken, Marvin, Giertzsch, Fabian, Hintze, Hartmut, God, Ralf

Enhancing Airworthiness Security: SysML-Based Approach to Modelling Security Scope Definitions

2025-01-0172To be published on 04/25/2025

Airworthiness certification of aircraft requires an Airworthiness Security Process (AWSP) to ensure safe operation under potential unauthorized interactions, particularly in the context of growing cyber threats. Regulatory authorities mandate the consideration of Intentional Unauthorized Electronic Interactions (IUEI) in the development of aircraft, airborne software, and equipment. As the industry increasingly adopts Model-Based Systems Engineering (MBSE) to accelerate development, we aim to enhance this effort by focusing on security scope definitions – a critical step within the AWSP for security risk assessment that establishes the boundaries and extent of security measures. However, our findings indicate that, despite the increasing use of model-based tools in development, these security scope definitions often remain either document-based or, when modeled, are presented at overly abstract levels, both of which limit their utility. Furthermore, we found that these definitions

Hechelmann, Adrian, Mannchen, Thomas

Model-Based Design and Energy Management of an Aeronautical Proton Exchange Membrane Fuel Cell System

2025-01-0150To be published on 04/25/2025

The growing demand for air transport requires efficient and sustainable power systems to meet the pressing need for decarbonizing the sector. A hybrid unit, consisting of a proton exchange membrane fuel cell system and a lithium-ion battery, is a suitable option due to the benefits of reduced gravimetric and volumetric impacts, along with the flexibility of energy management strategies. This work addresses, using a model-based approach, the issue of integrating these electrochemical devices into the aircraft’s electrical architecture, considering both design and energy management aspects. Two scenarios are explored to match the DC bus line voltage requirements. In the first, the fuel cell system nominal power is kept constant, while the number of DC/DC converters operating in parallel is assessed by constructing bi-dimensional maps derived from literature. These maps relate the converter’s maximum deliverable power to the input and desired output voltage. The second scenario introduces

Aliberti, Paolo, Sorrentino, Marco, Cuomo, Fabrizio, Napolitano, Ciro

A New Test Rig for Electrically Actuated Landing Gear and Brake of a Small Transport Aircraft

2025-01-0161To be published on 04/25/2025

Performing highly representative tests of aircraft equipments is a critical feature for gaining utmost confidence on their ability to perform flawlessly in flight under the entire spectrum of operating conditions. This can also contribute to accelerate the certification process of a new equipment. A research project (E-LISA) was performed in recent years, as part of the european funded Clean Sky 2 framework, with the objective of building an innovative facility for testing an electrically actuated landing gear and brake for a small air transport. The project eventually led to the development and construction of an Iron Bird able to reproduce in a realistic and comprehensive way a full variety of landing test cases consistent with certification specifications and landing histories available in the repository of the airframer. The Iron Bird that was eventually developed is a multi-functional intelligent and easy reconfigurable facility integrating hardware and software allowing to

De Martin, Andrea, Jacazio, Giovanni, Bertolino, Antonio

Segment Manipulator Retrofit

2025-01-0159To be published on 04/25/2025

A segment manipulator machine was in service nineteen years. Many of the control components were out of date and hard to obtain. Customer engaged Electroimpact to upgrade using the latest state-of-art controls. The program from the previous control system could not be reused. A “layup mandrel” is a form that is used to lay carbon fiber. The layup mandrel for a wide body aircraft fuselage section consists of six segments. The mandrel is made up of segments so that it can be assembled and disassembled from the inside. The segments are Crown, Upper Left, Upper Right, Lower Left, Lower Right, and Keel. For each build the mandrel is assembled with a segment manipulator machine, wound with carbon fiber tape, clad, and baked in an autoclave. Then the mandrel is disassembled with a segment manipulator machine leaving the cured carbon fiber shell behind. The segments are refurbished and brought to the assembly area on segment carts for the next build. Segments each weigh in the vicinity of 3000

Luker, Zachary, Donahue, Michael

Semi-Automatic Riveter G39 Replacement

2025-01-0160To be published on 04/25/2025

Zieve, Peter, Reznicek, Jeffrey

Sustainable Design of Automotive Batteries

2025-01-0001To be published on 04/18/2025

A consequence of the automotive industry's shift to electrification is that a significantly higher percentage of a vehicle's lifecycle CO₂ emissions occur during the production phase. As a result, vehicle manufacturers and suppliers must shift the focus of product development from the 'in-use phase only' to optimizing the complete product lifecycle. The proper design of a battery has the highest impact to all other phases following in the life-cycle. It influences the selection of materials, the manufacturing, in-use and end of life, respectively the recycling and recycling yield for a circular economy. Using real-life examples the paper will explain what are the main parameters necessary for designing a sustainable battery. What are the low hanging fruits to be considered? In addition, it will elaborate on the relation as well as the impacts to other KPIs like safety, costs and life-time of the battery. Finally it will round up in an outlook on how batteries will evolve in the future

Braun, Andreas, Rothbart, Martin

High-Performance and Stable Three-Way Catalyst Achieved via Ultrasonic Treatment for Gasoline Vehicle Emission Control

2025-01-8480To be published on 04/01/2025

Three-way catalysts (TWCs) containing significant amounts of precious metals are commonly employed to purify exhaust emissions (CO, NOx, and THC) from gasoline-powered vehicles. A critical factor contributing to TWC degradation is the sintering of these precious metals. Maintaining the appropriate particle size and distribution of the metals is essential for optimal catalyst performance. In this study, palladium (Pd) nanoparticles with a uniform size were synthesized using ethylene glycol as a reductant under ultrasonic conditions, yielding particles in the range of 3 nm to 5 nm. These Pd nanoparticles were subsequently used to prepare three-way catalysts on cordierite substrates supplied by Corning (China) Inc. Chemisorption analysis revealed that the Pd active component in the catalysts prepared via the ultrasonic method exhibited higher dispersion than the state-of-the-art commercial catalysts. The aged catalysts were obtained after 150 hours of aging following the General Motors

Hao, Shijie, Lv, Yanan, Wang, Weidong, Rao, Chao, Wei, Wei, Mao, Bingbin, Chen, Tao, Zhao, Huawang

Hierarchical Feature-based Localization using Scene Graphs in Off-road Navigation

2025-01-8046To be published on 04/01/2025

While numerous advancements have been made in autonomous navigation for structured indoor and outdoor environments, these solutions often do not generalize well to off-road settings. There are unique challenges in such settings such as unreliable GPS, limited computational and memory resources, and sparse environmental features, making navigation particularly difficult. In our work, we propose a novel data structure called Hierarchical Dynamic Scene Graphs (HDSG) to address these challenges. HDSG captures environmental information at different resolutions, integrating both geometric and semantic features. It enables various navigation tasks such as localization, loop closure, and human interaction through the visualization of environmental features for remote operators. We evaluated the performance of localizing a robot's position within the world frame by comparing compact spatial descriptors extracted from semi-consecutive scene graphs, derived from 3D LiDAR point clouds. Compared to

Alam, Fardifa Fathmiul, Luricich, Federico, Li, Nianyi, Jia, Yunyi, Li, Bing

Improving Vehicle Localization Confidence Under Different Road Geometries

2025-01-8043To be published on 04/01/2025

A significant challenge to the scalability of automated driving systems is the potential unavailability of GPS information for localization. To address this issue, a methodology using a static map of road and lane geometry is proposed that ensures reliable navigation for automated vehicles in GPS-denied situations. In this study, a dead reckoning system based on vehicle kinematics is implemented by onboard sensor data from the vehicle's Controller Area Network (CAN). The drift in the dead reckoning position estimate is reduced by using an arc-length based map matching approach. However, the map-matching approach has some inaccuracies in the longitudinal position estimate leading to error accumulation, the drift in the dead reckoning position estimate is eliminated by using an arc-length based map matching approach. This innovative approach was tested and validated at various safety-critical intersection scenarios, including four-way intersection, roundabout, slip-lane intersection, and

Javed, Nur Uddin, Singh, Yuvraj, Tan, Shengzhe, Ahmed, Qadeer

Parameter-Free Model-Free Deadbeat Predictive Current Control Based on Optimal Harmonic Current Injection

2025-01-8587To be published on 04/01/2025

Deadbeat Predictive Current Control (DPCC) has become a promising control method due to its excellent dynamic performance. However, the control effectiveness of traditional methods is limited by the machine parameters set in advance, which inevitably reduces the parameter robustness of the method. When machine parameters change due to factors like temperature, the mismatch between the actual values and the parameters set in the controller leads to a decline in DPCC performance, and may even cause system instability. To address this issue of parameter dependency, this paper proposes an adaptive parameter-free model-free deadbeat predictive current control (PF-MFDPCC) method suitable for interior permanent magnet synchronous motors (IPMSM). The method characterizes the error between the estimated machine parameter values and the true values by the difference between the sampled current and the reference current, and determines the required injected harmonic current by combining the

Guo, Rong, Gu, hongyang

Energy consumption optimization of commercial electric bus in Indian city driving condition using two speed transmission

2025-01-8504To be published on 04/01/2025

ABSTRACT Currently automobile industries are shifting towards electric powertrains from conventional internal combustion engines. With increase in use of electric vehicle, more focus is to increase the driving range of vehicle. As of now, most of the OEMs are using single speed transmission in their electric buses. Single speed transmission is effective in road having less traffic condition but during heavy traffic condition (like Mumbai city application), performance of motor gets deteriorated. In heavy traffic condition (city application), operating points of motor goes into less efficiency regions which results in high energy consumption. It will also affect the regeneration. In this study, focus is on commercial vehicle like electric buses. If there is a need to increase driving range, energy consumption must be optimized. Thus, higher energy consumption in heavy traffic condition can be managed by using multiple gear ratio. With use of optimum gear ratio, motor operating points

Saurabh, Saurabh, Amancharla, Naga Chaithanya, Bhardwaj, Rohit, Gadve, Dhananjay

A Motion-Aware Enhanced LiDAR ICP SLAM Framework for High-Speed Autonomy

2025-01-8044To be published on 04/01/2025

Towards the goal of real-time navigation of autonomous robots, the Iterative Closest Point (ICP) based LiDAR odometry methods are a favorable class of Simultaneous Localization and Mapping (SLAM) algorithms for their high performance and efficiency. In the context of autonomous vehicles, which tend to be high motion scenarios, ICP-based SLAM algorithms provide a relatively robust and real-time localization and mapping framework, paving the way for full autonomy. However even with the recent methods, the traditional SLAM challenges persist, where odometry drifts under adversarial conditions such as featureless or dynamic environments, and under high motion of the robot. In this paper we present a motion aware, enhanced LiDAR ICP SLAM framework. We have three contributions: a novel ICP cost function that yields faster and more robust convergence compared to the state of the art methods, a sophisticated motion constraint that maintain robot localization under sudden motion changes, and

Kokenoz, Cigdem, Shaik, Toukheer, Sharma, Abhishek, Pisu, Pierluigi, Li, Bing

Do aftermarket and original equipment forward collision warning systems respond the same to vehicles and pedestrians?

2025-01-8677To be published on 04/01/2025

Automatic emergency braking and forward collision warning (FCW) systems are equipped to about 32% of registered vehicles in the U.S (Highway Loss Data Institute, 2024). Retrofitting vehicles with aftermarket devices can accelerate the adoption of FCW, but it is unclear if aftermarket systems perform similarly to original equipment manufacturer (OEM) systems. The performance of four aftermarket windshield-mounted FCW systems was evaluated in various Insurance Institute for Highway Safety (IIHS) rear-end and pedestrian crash avoidance tests and compared with previously tested OEM systems. The presence and timing of FCWs were measured when vehicles approached a stationary passenger car at 20,40,50,60 and 70 km/h, motorcycle and dry van trailer at 50,60, and 70 km/h, adult pedestrian at 40 and 60 km/h, and child pedestrian crossing the road at 20 and 40 km/h. Equivalence testing was used to determine if FCW performance was similar between aftermarket and OEM systems. OEM systems provided a

Kidd, David, Floyd, Philip, Aylor, David

Developing a Safety Management System for the Automated Vehicle Industry

2025-01-8673To be published on 04/01/2025

Safety Management Systems (SMS) have demonstrated value in many safety-critical industries and are now increasingly being developed and deployed in the automated driving system (ADS)-equipped vehicle (AV) sector. Industries with a longer history of SMS deployment have established SMS standards tailored to their specific industry. Several frameworks for an AV industry SMS have been proposed or are currently under development. However, these frameworks borrow heavily from the aviation industry although the AV and aviation industries differ in many significant ways. In this context, there is an important need to review the approach to develop an SMS that is tailored specifically to the AV industry, building on lessons learned from other safety-sensitive industries. This paper outlines a proposed SMS framework for the AV industry based on robust taxonomy development and validation criteria.

Wichner, David, Wishart, Jeffrey, Sergent, Jason, Swaminathan, Sunder

Dynamic Driving Task Assessment Scores for Scenarios Navigated by an OEM ADS-Equipped Vehicle

2025-01-8672To be published on 04/01/2025

One of the major issues facing the automated driving system (ADS)-equipped vehicle (AV) industry is how to evaluate the performance of an AV as it navigates a given scenario. The development and validation of a sound, consistent, and transparent dynamic driving task (DDT) assessment (DA) methodology is a key component of the safety case framework (SCF) of the Automated Vehicle – Test and Evaluation Process (AV-TEP) Mission, a collaboration between Science Foundation Arizona and Arizona State University. The DA methodology was presented in earlier work, and includes the DA metrics from the recently published SAE J3237 Recommended Practice. This work implements the methodology with an AV developed by OEM May Mobility in five diverse scenarios: (1) VRU crossing in front of the AV’s path, (2) an oncoming vehicle entering the AV’s lane, (3) a vehicle executing a three-point turn encroaches into the AV’s path, (4) the AV departing its lane in a parking lot, and (5) the AV exhibiting

Wishart, Jeffrey, Rahimi, Shujauddin, Swaminathan, Sunder, Zhao, Junfeng, Como, Steven Gerard

OPTIMAL INVESTIGATION ABOUT CAB OF BSC RACING CAR BASED ON ERGONOMICS

2025-01-8669To be published on 04/01/2025

In the Baja competition, the racing cars need to run under a variety of complex off-road conditions such as pebble road, shell pit, the road with many broken stones, hump, water puddle and so on，in the endurance race，the driver even has to drive continuously for four hours. In the process of this high-intensity and high-concentration race, the irrational designs of cab in ergonomics will easily cause the driver's visual and handling fatigue, so that the driver's attention is not concentrated，and cause the security accidents. Moreover, the lower back pain, sciatic nerve discomfort, lumbar spine diseases and other occupational diseases are basically caused by uncomfortable driving posture and unreasonable manipulation interface, and these have a lot to do with unreasonable ergonomic designs. In order to solve the unreasonable designs of the cab in ergonomics and improve the safety and comfort of the driver, first of all, establish the overall model of BSC racing car in Catia to obtain a

Liu, Yuzhou, Liu, Silang

Driving Under the Influence: A Review of Fitness to Drive, Drug-Induced Impairments, and Simulation Testing

2025-01-8666To be published on 04/01/2025

This literature review examines the concept of fitness to drive and how it can be affected by drugs consumption. The Systematic Literature Review (SLR) methodology is used to analyse the Literature, exploiting Scopus, Consensus and Elicit databases. Firstly, the paper presents research across mechanical engineering and related fields to establish a comprehensive and multidisciplinary understanding of how fitness to drive is evaluated. This includes a definition of the term and the identification of the protocols used for its assessment. Secondly, the emphasis is on the impact of drug use on driving performance, excluding alcohol and cannabis. Driving simulators represent a valid possibility for analysing such effects in a safe, controlled and replicable environment. They are presented considering their most relevant characteristics and the measurements collected for the driver's state analysis. Key findings reveal a lack of a comprehensive taxonomy for fitness to drive, resulting in

Uccello, Lorenzo, Nobili, Alessandro, Pasina, Luca, Novella, Alessio, Elli, Chiara, Mastinu, Gianpiero

Analysis of the Event Data Recorder vehicle system data of a GM Vehicle Intelligence Platform Airbag Control Module (SDM50)

2025-01-8714To be published on 04/01/2025

The primary function of an Airbag Control Module (ACM), referred to as the Sensing and Diagnostic Module (SDM) by General Motors (GM), is to detect crashes, discriminate crashes, evaluate crash severities, deploy the appropriate restraints, including airbags and pretensioners, and perform system diagnostics. A secondary function of the SDM is to act as an Event Data Recorder (EDR) which records data during the time periods just prior to (pre-crash) and during a crash event. This data consists of restraint and vehicle system data which is collected, processed, and stored in the EDR. Data stored in the EDR is intended to be retrieved after a crash. This data provides operational information on the vehicle’s occupant protection system and other vehicle systems to assess system performance, aid in crash reconstruction, and support improved vehicle safety. A series of vehicle test maneuvers were conducted while injecting a non-deployment crash pulse directly into the SDM to cause the SDM to

Smyth, Brian, Crosby, Charles L, Bickhaus, Ryan, Smith, James, Edmunds, Dustin, Floyd, Donald, Modi, Vipul, Outlaw, RaShawndra D., Wright, Jeff

Highly accurate Machine Learning models for Automotive Crash applications using CAE centric AI/ML Platform

2025-01-8719To be published on 04/01/2025

In the automotive industry, there have been many efforts of late in using Machine Learning tools to aid virtual simulation and decrease product development time and cost. As the simulation world grapples with how best to incorporate ML techniques, two main challenges are evident. There is the risk of not knowing if the trained model is sound enough to drive the design. In addition, the complexity of porting simulation data back and forth to a ML software can make the process cumbersome. We would like to put forth a highly accurate and comprehensive one-stop ML workflow that has been implemented within a commercially available CAE driven platform called DEP MeshWorks. MeshWorks is used for rapid concept CAE and CAD model generation and parametrization. The AI platform within Meshworks leverages the inherent best-in-class parameterization capability to help rapidly generate data for training purposes. It is relatively quick to set up a fully parameterized CAE model and vary design

Krishnan, Radha

Commercial Vehicle Proximal Load Monitoring through measuring Spring Deflection

2025-01-8718To be published on 04/01/2025

In the realm of commercial vehicles, particularly in developing countries where they are primarily used for transporting goods, Overloading presents significant risks, such as vehicle imbalance, severe accidents, and substantial financial losses. This problem is particularly pronounced in developing markets, contributing to frequent incidents of overloading. Such conditions not only lead to structural damage but also heighten the danger to all road users. Efficient load monitoring systems are crucial for maintaining vehicle stability by balancing cargo loads and preventing accidents related to overloading. Ensuring proper load distribution and monitoring is essential for maintaining operational safety and efficiency in commercial vehicles. Current methods for monitoring cargo loads often rely on manual checks or complex sensors, providing limited feedback and reactive solutions to prevent overloading incidents. To address these challenges, this paper introduces a novel approach that

Katta, Eva, Maji, Kundan, Saha, Satya, Tiwari, Sanjay

Examination of the Data Structures of the Bendix Data Recorder

2025-01-8712To be published on 04/01/2025

Bendix® EC-80™ and certain EC-60™ ABS control units contain an event data recorder called the Bendix® Data Recorder (BDR). Raw BDR data is obtained using commercially available software, however, the translation of the raw data into an event report has only been performed by the manufacturer. In this paper, the raw data structures of the commercially available datasets are examined. It is demonstrated that the data follows uniform and repeatable patterns. The raw BDR data is converted into a conventional report and then validated against translation reports performed by the manufacturer. The techniques outlined in this research allow investigators to access and analyze BDR records independently of the manufacturer and in a way previously not possible.

DiSogra, Matthew, Hirsch, Jeffrey, Yeakley, Adam

Analysis and Comparison of Metrics to Assess Submarining Behavior with the Hybrid III 5th Percentile Dummy in the Rear Seat

2025-01-8711To be published on 04/01/2025

Real-world data show that abdominal loading due to a poor pelvis-belt restraint interaction is one of the primary causes of injury in belted rear-seat occupants, highlighting the importance of being able to assess it in crash tests. This study analyzes the phenomenon of submarining using video, time histories, and statistical analysis of data from a Hybrid III 5th female dummy seated in the rear seat of passenger vehicles in moderate overlap frontal crash tests. This study also proposes different metrics that can be used for detecting submarining in full-scale crash tests. The results show that apart from the high-speed videos, when comparing time-series graphs of various metrics, using a combination of iliac and lap belt loads was the most reliable method for detecting submarining. Five metrics from the dynamic sensors (the maximum iliac moment, maximum iliac force drop in 1 ms, time for 80% drop from peak iliac force, maximum pelvis rotation, and lumbar shear force) were all

Jagtap, Sushant R, Jermakian, Jessica S, Edwards, Marcy A

Tire Thermal Model with State Observer Integration for Enhanced Real-Time Temperature Prediction

2025-01-8756To be published on 04/01/2025

This paper focuses on the development of a tire thermal model for automotive applications, addressing the challenge of accurately predicting tire temperatures on different layers of the tire, under various driving conditions. The primary goal is to enhance the understanding of tire temperature behavior to improve safety, performance, and durability. The research utilizes a physics 1-D model for the tire, from which a system of differential equations, describing the interaction between different layers of the tire, is derived. Furthermore, a state observer is used to estimate tire temperatures, using Tire Pressure Monitoring System (TPMS) measurements to correct model predictions. In particular, the TPMS measurements are assumed to be sufficient to exclude the additional thermal contributions coming from the rims and disk brakes, which simplifies the model, making it more suitable for real-time applications. A calibration procedure is defined for deriving the model parameters, based on

Longobardi, Armando, Balaga, Sanjay, labella, Mario, Gorine, Mohamed El Amine

Research on road-sense simulation algorithm and analysis of its effect on different steering wheels

2025-01-8753To be published on 04/01/2025

With the continuous development of automotive intelligence, cars increasingly want chassis to be more intelligent, electronically controlled, integrated and lightweight. Therefore, the steer-by-wire system, controlled by the line, with high precision and fast response, can provide better flexibility, stability and comfort for the car and can well meet the above requirements, has been widely concerned. As the steer-by-wire system eliminates the mechanical structure, the road sense cannot be directly transmitted to the steering wheel. The road sense obtained according to the vehicle state or combined with the driving environment planning needs to be applied to the steering wheel through the road sense motor to complete the simulation of the road sense so that the driver can feel the feedback similar to driving the traditional steering vehicle. In this way, the driving experience of the driver can be increased. It can also enhance driving safety, so it is very important to study the road

Li, Shang, Kaku, Chuyo, Zheng, Hongyu, Zhang, Yuzhou

Load Cell Data Analysis from Frontal NCAP Tests to Assess Aggressivity and Compatibility of Battery Electric and Internal Combustion Engine Vehicles

2025-01-8746To be published on 04/01/2025

A total of 368 frontal New Car Assessment Program (NCAP) tests (including 24 tests with Battery Electric Vehicles (BEVs)) with high-resolution load cell data were analyzed to investigate vehicle crash compatibility, especially between Internal Combustion Engine Vehicles (ICEVs) and BEVs. An Indirect Frontal Crash Model (IFCM) for Full-Overlap (FO) Vehicle-to-Moving Deformable Barrier (V2MDB) using load cell data from frontal NCAP tests was developed to assess vehicle aggressivity. An analytical solution of the IFCM for FO/V2MDB was obtained and used to develop a new aggressivity metric. In addition, the Max. Standard Deviation (SD) of load cell forces was used to assess vehicle front-end homogeneity. In the case studies, vehicle compatibility was assessed by the new aggressivity metric and Max. SD, along with typical frontal crash metrics.

Park, Chung-Kyu

Numerical Modeling of a Sandwich Structure Integrated with Shear Thickening Fluid (STF) for Impact Energy Absorption

2025-01-8745To be published on 04/01/2025

Shear Thickening Fluid (STF) exhibits tunable stiffness under varying loading velocities, making it an ideal candidate for energy absorption in transportation systems subjected to complex loading conditions, such as crash scenarios. Recent research highlights that integrating STF with conventional structures can significantly enhance overall energy absorption performance. In this study, we developed a novel sandwich plate by combining a newly designed bio-inspired 3D periodic structure with STF, aiming to create an advanced energy absorber. A finite element model of this system was developed and validated against experimental data. Using this numerical model, we conducted comprehensive impact simulations to investigate the effects of impact velocity and STF viscosity on key structural responses, including peak and mean stress, as well as energy absorption. The contributions of both the fluid and solid components were analyzed. Our findings indicate that the integrated structure

Zhu, Feng, Deb, Anindya

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