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A novel design for a radial field switching reluctance motor with a sandwich-type C-core architecture is proposed. This approach combines elements of both traditional axial and radial field distribution techniques. This motor, similar to an in-wheel construction, is mounted on a shared shaft and is simple to operate and maintain. The rotor is positioned between the two stators in this configuration. The cores and poles of the two stators are separated from one another both magnetically and electrically. Both stators can work together or separately to produce the necessary torque. This adds novelty and improves the design’s suitability for use with electrical vehicles (EVs). A good, broad, and adaptable torque profile is provided by this setup at a modest excitation current. This work presents the entire C-core radial field switched reluctance motor (SRM) design process, including the computation of motor parameters through computer-aided design (CAD). The CAD outputs are verified via
Patel, Nikunj R.Mokariya, Kashyap L.Chavda, Jiten K.Patil, Surekha
ABSTRACT This paper presents a method to mitigate high latency in the teleoperation of unmanned ground systems through display prediction and state estimation. Specifically, it presents a simulation environment which models both sides of the teleoperation system in the laboratory. The simulation includes a teleoperated vehicle model to represent the dynamics in high fidelity. The sensors and actuators are modeled as well as the communication channel. The latency mitigation approach is implemented in this simulation environment, which consists of a feed-forward vehicle model as a state estimator which drives a predictive display algorithm. These components work together to help the operator receive immediate feedback regarding his/her control actions. The paper contains a technical discussion of the design as well as specific implementation. It concludes with the presentation of some experimental data which demonstrate significant improvement over the unmitigated case
Brudnak, Mark J.
ABSTRACT This paper describes the role of Modeling and Simulation (M&S) as a critical tool which must be necessarily used for the development, acquisition and testing of autonomous systems. To be used effectively key aspects of development, acquisition and testing must adapt and change to derive the maximum benefit from M&S. We describe how development, acquisition and testing should leverage and use M&S. We furthermore introduce and explain the idea of testable autonomy and conclude with a discussion of the qualities and requirements that M&S needs to have to effectively function in the role that we envision. Citation: J. Brabbs, S. Lohrer, P. Kwashnak, P. Bounker, M. Brudnak, “M&S as the Key Enabler for Autonomy Development, Acquisition and Testing”, In Proceedings of the Ground Vehicle Systems Engineering and Technology Symposium (GVSETS), NDIA, Novi, MI, Aug. 13-15, 2019
Brabbs, JohnLohrer, ScottKwashnak, PaulBounker, PaulBrudnak, Mark
ABSTRACT Protection Engineering Consultants (PEC) has performed static and dynamic-pendulum tests on bolted and welded connection sub-assemblies to generate data for development and validation of modeling approaches capable of accurately predicting the behavior of connections exposed to shock loads. The connections consisted of Rolled Homogeneous Armor (RHA) steel plates, Grade 8 bolts, and fillet welds of ER80-S wire, as typically used in armored vehicles. A summary of the forty physical tests on nine connection configurations are provided along with strain gage and Digital Image Correlation (DIC) data. The specimens were designed to have typical failure modes, i.e. bolt shear, plate tear-out, and weld shear fracture. Using these data, high-fidelity numerical models were developed, with exceptionally good comparisons to the experimental data. During the development of the numerical models, crucial modeling parameters were identified and were shown to have significant influence to the
Hadjioannou, MichalisBarsotti, MattSammarco, EricStevens, David
ABSTRACT Rubber is the main element of tires and the outside layer of tracks. Tire and track heating is caused by hysteresis effects due to the deformation of the rubber during operation. Tire temperatures can depend on many factors, including tire geometry, inflation pressure, vehicle load and speed, road type and temperature and environmental conditions. The focus of this study is to develop a finite element approach to computationally evaluate the temperature field of a steady-state rolling tire and track. The 3D thermal analysis software Radtherm was applied to calculate the average temperature of tread and sidewall, and the results of Radtherm agreed with ABAQUS results very well. The distributions of stress and strain energy density of the rolling tracks were investigated by ABAQUS as well. The future works were finally presented
Tang, TianJohnson, DanielLedbury, EmilyGoddette, ThomasFelicelli*, Sergio D.Smith, Robert E.
ABSTRACT The modeling of a buried charge is a very complex engineering task since many Design Variables need to be considered. The variables in question are directly related to the method chosen to perform the analysis and the process modeled. In order to have a Predictive Tool two main objectives have to be carried out, the first is a verification of the numerical approach with experimental data, the second objective is a sensitivity study of the numerical and process parameters. The emphasis of the present study covers the second objective. To perform this task a comprehensive sensitivity study of fourteen Design Variables was completed which required 1000+ computational hours. The modeling approach that was chosen was the Discrete Particle Method (DPM) to model the Soil and HE and the Finite Element Method for the Structure. The basis for the study was a blast event applied to a model of the TARDEC Generic Vehicle Hull. The Response Parameter was chosen to be the Total Blast Impulse
Jensen, Morten RikardSmith, Wilford
ABSTRACT Modelling and simulation together with well-defined development processes have become key approaches for creating high quality, reliable consumer products. This is particularly true for passenger cars and trucks. In parallel, the evolving area of mobile ground robotics has found a variety of useful applications over the past twenty years: helping users accomplish tasks in hospitals, warehouses, factories, and on the battlefield. While many of these robotic systems have proven highly valuable, many also lack the mobility, flexibility, reliability and/or robustness desired by the users. In this paper, the authors posit that these non-idealities are in part the result of underutilization of modelling and simulation and an appropriate processes to implement them. This underutilization is partially due to a historical lack of appropriate M&S tools. Recently, however, a new generation of real-time, highly visualized, interactive tools has emerged that has the potential to make a
Rohde, Mitchell M.Rohde, Steve M.
With the rapid advancement of Unmanned Aerial Vehicle (UAV) technology, their assigned missions have become significantly more intricate. Individual UAVs are no longer sufficient to meet these diverse and demanding requirements. There is now a shift towards employing multiple UAVs operating collaboratively to address complex tasks, replacing the reliance on singular units. This study focuses on the complexities of coordinated flight within UAV formations. A dynamic consensus optimal control algorithm is proposed for distributed formations, grounded in optimal control theory. Furthermore, the enhanced control method is validated via simulation on a semi-physical visualization platform, effectively closing the gap between real-world formation requirements and simulation outcomes. The results from these simulations underscore that the proposed method effectively preserves UAV formation integrity and demonstrates exceptional applicability in real-world scenarios
Li, WeiZhou, HanyunShi, JiekaiCheng, WeinanWang, FangBai, Jie
Integrating 3D point cloud and image fusion into flying car detection systems is essential for enhancing both safety and operational efficiency. Accurate environmental mapping and obstacle detection enable flying cars to optimize flight paths, mitigate collision risks, and perform effectively in diverse and challenging conditions. The AutoAlignV2 paradigm recently introduced a learnable schema that unifies these data formats for 3D object detection. However, the computational expense of the dynamic attention alignment mechanism poses a significant challenge. To address this, we propose a Lightweight Cross-modal Feature Dynamic Aggregation Module, which utilizes a model-driven feature alignment strategy. This module dynamically realigns heterogeneous features and selectively emphasizes salient aspects within both point cloud and image datasets, enhancing the differentiation between objects and the background and improving detection accuracy. Additionally, we introduce the Lightweight
Feng, XiaoyuZhang, RenhangChu, ZhengWei, LinaBian, ChenDuan, Linshuai
ABSTRACT The recent climate change plan for the United States Army states that hybridized combat vehicles will enter the fleet by 2050. The Bradley Fighting Vehicle (BFV) and its family of vehicles are prime candidates for hybridization. This paper sets out to perform a drive cycle analysis for the BFV using its traditional powertrain along with hybridized powertrains. The analysis considers both series and parallel hybrid architectures, where the size of the batteries are based on modifications to the existing powertrain. Three different drive cycles are considered – stationary, highway, and off-road. The model accounts for accelerative forces, transmission losses, cooling losses, drag, road grade, tractive losses, and ancillary equipment. The results indicate that both parallel and series hybrids provide reduced fuel consumption and increased range. Of the two, the series hybrid architecture provides more overall benefits. The study concludes by discussion of the technical challenges
Razon, CourtneyMittal, Vikram
ABSTRACT As unmanned ground vehicle technology matures and autonomous platforms become more common, such platforms will invariably be in close proximity to one another both in formation and independently. With an increasingly crowded field, the risk of collisions between these platforms grows, and with it the need for path deconfliction. This paper presents two complementary technological developments to this end: a pipeline for affirmatively identifying and classifying dynamic objects, e.g., vehicles or pedestrians; and a pipeline for preventing collisions with such objects. The efficacy of these techniques is demonstrated in simulation, and validation on robotic platforms will be undertaken in the near future. Citation: Matthew Grogan, “Dynamic Object Collision Avoidance for Autonomous Multi-Vehicle Systems in the Robotic Technology Kernel”, In Proceedings of the Ground Vehicle Systems Engineering and Technology Symposium (GVSETS), NDIA, Novi, MI, Aug. 13-15, 2019
Grogan, Matthew
Navigating Unmanned Aerial Vehicles (UAVs) in urban airspace poses significant challenges for fast and efficient path planning due to the environment's complexity and dynamism. However, the existing research on UAV path planning has ignored the speed of algorithmic convergence and the smoothness of the generated path, which are critical for adapting to the dynamic changing of the urban airspace as well as for the safety of ground personnel, and the UAV itself. In this study, we propose an enhanced Ant Colony Optimization (ACO) algorithm that incorporates two heuristic functions: the compass heuristic and the inertia heuristic. These functions guide the ant agents in their movement towards the destination, aiming for faster convergence and smoother trajectories. The algorithm is evaluated using a gray-scale lattice map generated from ground personnel risk data in Suzhou City. The results indicate that the improved ACO path planning algorithm demonstrates both efficiency and quality
Wang, BofanZhao, ZhouyeHu, BoyaLiu, YufanRu, XiaoyuTong, ZiyueJia, Qing
The life and safety of a battery are closely linked to temperature. Designing an effective thermal management system relies on a thorough understanding and analysis of the thermal properties and mechanisms of the battery. Over time, as batteries are used, their thermal characteristics change due to variations in internal SEI thickness, the deterioration of the active material structure, gas production, and electrolyte consumption, all of which are associated with the aging process. In this paper, experiments on both NCM and LFP batteries were made to measure the heat generation characteristics by adiabatic calorimeter. The results showed that the impact of calendar aging on battery heat generation exhibited completely different patterns for the lithium-ion batteries of the two material systems mentioned above. This paper provides guidance for the optimization of heat generation characteristics of battery and the calibration of heat source in the design of battery thermal management
Li, HaibinZhao, HongweiLiu, DinghongHu, Qiaosheng
In this paper, a single-chip based design for an automotive 4D millimeter -wave radar is proposed. Compared to conventional 3D millimeter-wave radar, this innovative scheme features a MIMO antenna array and advanced waveform design, significantly enhancing the radar's elevation measurement capabilities. The maximum measurement error is approximately ±0.3° for azimuth within ±50° and about ±0.4° for elevation within ±15°. Extensive road testing had demonstrated that the designed radar can routinely measure targets such as vehicles, pedestrians, and bicycles, while also accurately detecting additional objects like overpasses and guide signs. The cost of this radar is comparable to that of traditional automotive 3D millimeter-wave radar, and it has been successfully integrated into a forward radar system for a specific vehicle model
Cai, YongjunZhang, XianshengBai, JieShen, Hui-LiangRao, Bing
With the capability of predicting detailed injury of occupants, the Human Body Model (HBM) was used to identify potential injuries for occupants in car impact events. However, there are few publications on using HBM in the aviation industry. This study aims to investigate and compare the head, neck, lumbar spine and thoracic responses of the Hybrid III and the THUMS (Total Human Model for Safety) model in the horizontal 26g and vertical 19g sled tests required by the General Aviation Aircraft Airworthiness Regulations. The HIC of THUMS and Hybrid III did not exceed the requirements of airworthiness regulations. Still, THUMS had higher intracranial pressures and intracranial stresses, which could result in brain injury to the occupants. In vertical impact, the highest stress of the neck of THUMS appears at the cervical spine C2 and the upper neck is easily injured; in horizontal impact, the cervical spine C7 has the highest load, and the lower neck is easily injured. Due to the low
Shi, XiaopengDing, XiangheGuo, KaiLiu, TianfuXie, Jiang
In non-cooperative environments, unmanned aerial vehicles (UAVs) have to land without artificial markers, which is a key step towards achieving full autonomy. However, the existing vision-based schemes have the common problems of poor robustness and generalization, and the LiDAR-based schemes have the disadvantages of low resolution, high power consumption and high weight. In this paper, we propose an UAV landing system equipped with a binocular camera to preform 3D reconstruction and select the safe landing zone. The whole system only consists of a stereo camera, and the innovation of the solution is fusing the stereo matching algorithm and monocular depth estimation(MDE) model to get a robust prediction on the metric depth. The whole landing system consists of a stereo matching module, a monocular depth estimation (MDE) module, a depth fusion module, and a safe landing zone selection module. The stereo matching module uses Semi-Global Matching (SGM) algorithm to calculate the
Zhou, YiBiaoZhang, BiHui
ABSTRACT An important aspect of any new ground vehicle acquisition program is an analytic understanding of the key performance, cost, risk and growth tradeoffs inherent with the system design. The Whole System Trades Analysis Tool (WSTAT) provides a holistic framework for modeling and understanding these tradeoffs. In this paper, we present the overarching WSTAT methodology and then consider a specific implementation for the Army’s Squad Multipurpose Equipment Transport (SMET) autonomous ground vehicle. Emerging results regarding high-level SMET design considerations are provided to demonstrate the types of decision support enabled by the WSTAT capability
Henry, Stephen M.Waddell, Lucas A.DiNunzio, Michael R.
ABSTRACT Thermal management systems (TMS) of armored ground vehicle designs are often incapable of sustained heat rejection during high tractive effort conditions and ambient conditions. The use of a latent heat energy storage system that utilizes Phase Change Materials (PCMs) is an effective way of storing thermal energy and offers key advantages such as high-energy storage density, high heat of fusion values, and greater stability in temperature control. Military vehicles frequently undergo high-transient thermal loads and often do not provide adequate cooling for powertrain subsystems. This work outlines an approach to temporarily store excess heat generated by the transmission during high tractive effort situations through use of a passive PCM retrofit thereby extending the operating time, reducing temperature transients, and limiting overheating. A numerical heat transfer model has been developed based around a conceptual vehicle transmission TMS. The model predicts the
Putrus, Johnathon P.Jones, Stanley T.Jawad, Badih A.Schihl, Peter
ABSTRACT Vehicle design today takes longer than it ever has in the past largely due to the abundance of requirements, standards, and new design techniques; this trend is not likely to change any time soon. This paper will explore how advancements in gaming engines can be leveraged to bring realistic visualization and virtual prototypes to the beginning of the design cycle, integrate subsystems earlier in the design, provide advanced simulation capabilities, and ensure that the final design not only meets the requirements but is fully vetted by stakeholders and meets the needs of the platform. The Unreal Engine and Bravo Framework can be used to bring this and more to vehicle designs to reduce design churn and bring better products to market faster. Citation: A. Diepen, O. Vazquez, A. Black, C. Gaff “Leveraging Simulation Tools to Accelerate Design,” In Proceedings of the Ground Vehicle Systems Engineering and Technology Symposium (GVSETS), NDIA, Novi, MI, Aug. 16-18, 2022
Diepen, AndyVazquez, OrlandoBlack, AndrewGaff, Chuck
ABSTRACT A methodology based on a combination of commercial software tools is developed for rendering complex acoustic scenes in real time. The methodology aims to bridge the gap between real time acoustic rendering algorithms which lack important physics for the exterior urban environment and more rigorous but computationally expensive geometric or wave-based acoustics software by incorporating pre-computed results into a real time framework. The methodology is developed by surveying the best in class commercial software, outlining a general means for accommodating results from each, and identifying areas where supplemental capability is required. This approach yields a real time solution with improved accuracy. Strengths and limitations in current commercial technologies are identified and summarized
Mattson, Steven GPolakowski, Stephen E.Pruetz, JeffSmith, RobJanicki, Phil
ABSTRACT Route planning plays an integral role in mission planning for ground vehicle operations in urban areas. Determining the optimum path through an urban area is a well understood problem for traditional ground vehicles; however, in the case of autonomous unmanned ground vehicles (UGVs), additional factors must be considered. For a UGV, perception, rather than mobility, will be the limiting factor in determining operational areas. Current ground vehicle route planning techniques do not take perception concerns into account, and these techniques are not suited for route planning for UGVs. For this study, perception was incorporated into the route planning process by including expected sensor accuracy for GPS, LIDAR, and inertial sensors into the path planning algorithm. The path planner also accounts for additional factors related to UGV performance capabilities that affect autonomous navigation
Durst, Phillip J.Goodin, ChristopherSong, PeilinDu, Thien K.
ABSTRACT The complexity of the current and future security environment will impose new and ever-changing challenges to Warfighter capabilities. Given the critical nature of Soldier cognitive performance in meeting these increased demands, systems should be designed to work in ways that are consistent with human cognitive function. Here, we argue that traditional approaches to understanding the human and cognitive dimensions of systems development cannot always provide an adequate understanding of human cognitive performance. We suggest that integrating neuroscience approaches and knowledge provides unique opportunities for understanding human cognitive function. Such an approach has the potential to enable more effective systems design – that is, neuroergonomic design – and that it is necessary to obtain these understandings within complex, dynamic environments. Ongoing research efforts utilizing large-scale ride motion simulations that allow researchers to systematically constrain
Oie, Kelvin S.Paul, Victor
ABSTRACT At the onset of the Second World War, it was noticed that equipment being shipped overseas to the frontlines arrived corroded. The Department of Defense rapidly escalated the use of corrosion inhibitors in packaging materials to reduce the severity of the corrosion of those assets. This paper provides an overview of vapor corrosion inhibitors, describes how they are incorporated into anti-corrosion covers, and summarizes field test results showing typical protection provided to Department of Defense assets. The paper describes the environmental conditions that warrant the use of anti-corrosion covers and presents independent ground vehicle focused return-on-investment analysis. Citation: David J. Sharman, Robert R. Danko, Bill Scheible, “Light-weight drapable anti-corrosion covers,” In Proceedings of the Ground Vehicle Systems Engineering and Technology Symposium (GVSETS), NDIA, Novi, MI, Aug. 15-17, 2023
Sharman, David JDanko, Robert R.Schieble, Bill