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1. RaceMOP: Mapless Online Path Planning for Multi-Agent Autonomous Racing using Residual Policy Learning

Author

Trumpp, Raphael, Javanmardi, Ehsan, Nakazato, Jin, Tsukada, Manabu, and Caccamo, Marco

Subjects
Computer Science - Robotics
Abstract

The interactive decision-making in multi-agent autonomous racing offers insights valuable beyond the domain of self-driving cars. Mapless online path planning is particularly of practical appeal but poses a challenge for safely overtaking opponents due to the limited planning horizon. To address this, we introduce RaceMOP, a novel method for mapless online path planning designed for multi-agent racing of F1TENTH cars. Unlike classical planners that rely on predefined racing lines, RaceMOP operates without a map, utilizing only local observations to execute high-speed overtaking maneuvers. Our approach combines an artificial potential field method as a base policy with residual policy learning to enable long-horizon planning. We advance the field by introducing a novel approach for policy fusion with the residual policy directly in probability space. Extensive experiments on twelve simulated racetracks validate that RaceMOP is capable of long-horizon decision-making with robust collision avoidance during overtaking maneuvers. RaceMOP demonstrates superior handling over existing mapless planners and generalizes to unknown racetracks, affirming its potential for broader applications in robotics. Our code is available at http://github.com/raphajaner/racemop., Comment: IEEE/RSJ International Conference on Intelligent Robots and Systems 2024

Published
2024

2. Zero-Knowledge Proof of Traffic: A Deterministic and Privacy-Preserving Cross Verification Mechanism for Cooperative Perception Data

Author

Tao, Ye, Javanmardi, Ehsan, Lin, Pengfei, Nakazato, Jin, Jiang, Yuze, Tsukada, Manabu, and Esaki, Hiroshi

Subjects
Computer Science - Networking and Internet Architecture, Computer Science - Cryptography and Security
Abstract

Cooperative perception is crucial for connected automated vehicles in intelligent transportation systems (ITSs); however, ensuring the authenticity of perception data remains a challenge as the vehicles cannot verify events that they do not witness independently. Various studies have been conducted on establishing the authenticity of data, such as trust-based statistical methods and plausibility-based methods. However, these methods are limited as they require prior knowledge such as previous sender behaviors or predefined rules to evaluate the authenticity. To overcome this limitation, this study proposes a novel approach called zero-knowledge Proof of Traffic (zk-PoT), which involves generating cryptographic proofs to the traffic observations. Multiple independent proofs regarding the same vehicle can be deterministically cross-verified by any receivers without relying on ground truth, probabilistic, or plausibility evaluations. Additionally, no private information is compromised during the entire procedure. A full on-board unit software stack that reflects the behavior of zk-PoT is implemented within a specifically designed simulator called Flowsim. A comprehensive experimental analysis is then conducted using synthesized city-scale simulations, which demonstrates that zk-PoT's cross-verification ratio ranges between 80 % to 96 %, and 80 % of the verification is achieved in 2 s, with a protocol overhead of approximately 25 %. Furthermore, the analyses of various attacks indicate that most of the attacks could be prevented, and some, such as collusion attacks, can be mitigated. The proposed approach can be incorporated into existing works, including the European Telecommunications Standards Institute (ETSI) and the International Organization for Standardization (ISO) ITS standards, without disrupting the backward compatibility.

Published
2023

3. Roadside LiDAR Assisted Cooperative Localization for Connected Autonomous Vehicles

Author

Jiang, Yuze, Javanmardi, Ehsan, Nakazato, Jin, Tsukada, Manabu, and Esaki, Hiroshi

Subjects
Computer Science - Robotics
Abstract

Advancements in LiDAR technology have led to more cost-effective production while simultaneously improving precision and resolution. As a result, LiDAR has become integral to vehicle localization, achieving centimeter-level accuracy through techniques like Normal Distributions Transform (NDT) and other advanced 3D registration algorithms. Nonetheless, these approaches are reliant on high-definition 3D point cloud maps, the creation of which involves significant expenditure. When such maps are unavailable or lack sufficient features for 3D registration algorithms, localization accuracy diminishes, posing a risk to road safety. To address this, we proposed to use LiDAR-equipped roadside unit and Vehicle-to-Infrastructure (V2I) communication to accurately estimate the connected autonomous vehicle's position and help the vehicle when its self-localization is not accurate enough. Our simulation results indicate that this method outperforms traditional NDT scan matching-based approaches in terms of localization accuracy., Comment: Accepted by 2023 International Conference on Intelligent Computing and its Emerging Applications

Published
2023
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4. Potential Field-based Path Planning with Interactive Speed Optimization for Autonomous Vehicles

Author

Lin, Pengfei, Javanmardi, Ehsan, Nakazato, Jin, and Tsukada, Manabu

Subjects
Computer Science - Robotics
Abstract

Path planning is critical for autonomous vehicles (AVs) to determine the optimal route while considering constraints and objectives. The potential field (PF) approach has become prevalent in path planning due to its simple structure and computational efficiency. However, current PF methods used in AVs focus solely on the path generation of the ego vehicle while assuming that the surrounding obstacle vehicles drive at a preset behavior without the PF-based path planner, which ignores the fact that the ego vehicle's PF could also impact the path generation of the obstacle vehicles. To tackle this problem, we propose a PF-based path planning approach where local paths are shared among ego and obstacle vehicles via vehicle-to-vehicle (V2V) communication. Then by integrating this shared local path into an objective function, a new optimization function called interactive speed optimization (ISO) is designed to allow driving safety and comfort for both ego and obstacle vehicles. The proposed method is evaluated using MATLAB/Simulink in the urgent merging scenarios by comparing it with conventional methods. The simulation results indicate that the proposed method can mitigate the impact of other AVs' PFs by slowing down in advance, effectively reducing the oscillations for both ego and obstacle AVs., Comment: Submitted to IEEE IECON 2023

Published
2023

5. Occlusion-Aware Path Planning for Collision Avoidance: Leveraging Potential Field Method with Responsibility-Sensitive Safety

Author

Lin, Pengfei, Javanmardi, Ehsan, Nakazato, Jin, and Tsukada, Manabu

Subjects
Computer Science - Robotics
Abstract

Collision avoidance (CA) has always been the foremost task for autonomous vehicles (AVs) under safety criteria. And path planning is directly responsible for generating a safe path to accomplish CA while satisfying other commands. Due to the real-time computation and simple structure, the potential field (PF) has emerged as one of the mainstream path-planning algorithms. However, the current PF is primarily simulated in ideal CA scenarios, assuming complete obstacle information while disregarding occlusion issues where obstacles can be partially or entirely hidden from the AV's sensors. During the occlusion period, the occluded obstacles do not possess a PF. Once the occlusion is over, these obstacles can generate an instantaneous virtual force that impacts the ego vehicle. Therefore, we propose an occlusion-aware path planning (OAPP) with the responsibility-sensitive safety (RSS)-based PF to tackle the occlusion problem for non-connected AVs. We first categorize the detected and occluded obstacles, and then we proceed to the RSS violation check. Finally, we can generate different virtual forces from the PF for occluded and non-occluded obstacles. We compare the proposed OAPP method with other PF-based path planning methods via MATLAB/Simulink. The simulation results indicate that the proposed method can eliminate instantaneous lateral oscillation or sway and produce a smoother path than conventional PF methods., Comment: Submitted to IEEE ITSC 2023

Published
2023

6. Time-to-Collision-Aware Lane-Change Strategy Based on Potential Field and Cubic Polynomial for Autonomous Vehicles

Author

Lin, Pengfei, Javanmardi, Ehsan, Tao, Ye, Chauhan, Vishal, Nakazato, Jin, and Tsukada, Manabu

Subjects
Computer Science - Robotics
Abstract

Making safe and successful lane changes (LCs) is one of the many vitally important functions of autonomous vehicles (AVs) that are needed to ensure safe driving on expressways. Recently, the simplicity and real-time performance of the potential field (PF) method have been leveraged to design decision and planning modules for AVs. However, the LC trajectory planned by the PF method is usually lengthy and takes the ego vehicle laterally parallel and close to the obstacle vehicle, which creates a dangerous situation if the obstacle vehicle suddenly steers. To mitigate this risk, we propose a time-to-collision-aware LC (TTCA-LC) strategy based on the PF and cubic polynomial in which the TTC constraint is imposed in the optimized curve fitting. The proposed approach is evaluated using MATLAB/Simulink under high-speed conditions in a comparative driving scenario. The simulation results indicate that the TTCA-LC method performs better than the conventional PF-based LC (CPF-LC) method in generating shorter, safer, and smoother trajectories. The length of the LC trajectory is shortened by over 27.1\%, and the curvature is reduced by approximately 56.1\% compared with the CPF-LC method., Comment: Accepted in IEEE Intelligent Vehicles Symposium (IV) 2023

Published
2023

7. Flowsim: A Modular Simulation Platform for Microscopic Behavior Analysis of City-Scale Connected Autonomous Vehicles

Author

Tao, Ye, Javanmardi, Ehsan, Nakazato, Jin, Tsukada, Manabu, and Esaki, Hiroshi

Subjects
Computer Science - Networking and Internet Architecture
Abstract

As connected autonomous vehicles (CAVs) become increasingly prevalent, there is a growing need for simulation platforms that can accurately evaluate CAV behavior in large-scale environments. In this paper, we propose Flowsim, a novel simulator specifically designed to meet these requirements. Flowsim offers a modular and extensible architecture that enables the analysis of CAV behaviors in large-scale scenarios. It provides researchers with a customizable platform for studying CAV interactions, evaluating communication and networking protocols, assessing cybersecurity vulnerabilities, optimizing traffic management strategies, and developing and evaluating policies for CAV deployment. Flowsim is implemented in pure Python in approximately 1,500 lines of code, making it highly readable, understandable, and easily modifiable. We verified the functionality and performance of Flowsim via a series of experiments based on realistic traffic scenarios. The results show the effectiveness of Flowsim in providing a flexible and powerful simulation environment for evaluating CAV behavior and data flow. Flowsim is a valuable tool for researchers, policymakers, and industry professionals who are involved in the development, evaluation, and deployment of CAVs. The code of Flowsim is publicly available on GitHub under the MIT license.

Published
2023

32. The Future of Flying Base Stations: Empirical and Numerical Investigations of mmWave-Enabled UAVs.

Author

Masaoka, Ryunosuke, Tran, Gia Khanh, Nakazato, Jin, and Sakaguchi, Kei

Subjects
RADIO wave propagation, DRONE aircraft, THEORY of wave motion, WIRELESS communications, NUMERICAL analysis
Abstract

Nowadays, wireless communications are ubiquitously available. However, as pervasive as this technology is, there are distinct situations, such as during substantial public events, catastrophic disasters, or unexpected malfunctions of base stations (BSs), where the reliability of these communications might be jeopardized. Such scenarios highlight the vulnerabilities inherent in our current infrastructure. As a result, there is growing interest in establishing temporary networks that offer high-capacity communications and can adaptively shift service locations. To address this gap, this paper investigates the promising avenue of merging two powerful technologies: Unmanned Aerial Vehicles (UAVs) and millimeter-wave (mmWave) transmissions. UAVs, with their ability to be operated remotely and to take flight without being constrained by terrestrial limitations, present a compelling case for being the cellular BSs of the future. When integrated with the high-speed data transfer capabilities of mmWave technology, the potential is boundless. We embark on a hands-on approach to provide a tangible foundation for our hypothesis. We carry out comprehensive experiments using an actual UAV equipped with an mmWave device. Our main objective is to meticulously study its radio wave propagation attributes when the UAVs are in flight mode. The insights gleaned from this hands-on experimentation are profound. We contrast our experimental findings with a rigorous numerical analysis to refine our understanding. This comparative study aimed to shed light on the intricacies of wave propagation behaviors within the vast expanse of the atmosphere. [ABSTRACT FROM AUTHOR]

Published
2024
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34. Overcoming Environmental Challenges in CAVs through MEC-based Federated Learning

Author

Wang, Zekun, Nakazato, Jin, Asad, Muhammad, Javanmardi, Ehsan, Tsukada, Manabu, Wang, Zekun, Nakazato, Jin, Asad, Muhammad, Javanmardi, Ehsan, and Tsukada, Manabu

Abstract

Connected autonomous vehicles (CAVs), through vehicle-to-everything communication and computing resources, enable the vital exchange of information. Although deep learning is crucial in this landscape, it requires extensive and intricate datasets covering all potential scenarios. Furthermore, this situation poses a hazard, as the likelihood of accidents associated with imbalanced datasets increases, particularly in scenarios where processing analysis is compromised due to fluctuating weather conditions. We propose a Federated Learning (FL) framework undergirded by Multi-Access Edge Computing (MEC) to counter these challenges. This local device-focused framework enhances task-specific models' caching and continual updating across various conditions. In a more specific sense, edge nodes (ENs) operate as MEC, each caching multiple dedicated models and serving as the aggregator as part of the FL process. Additionally, we have engineered two innovative algorithms that categorize various states into multiple classes, thereby ensuring the efficient utilization of computing resources in ENs. Simulation results substantiate the effectiveness of our approach, showing that the proposed dedicated model consistently outperforms a general model designed for all situations., Part of ISBN 9798350335385QC 20231123

Published
2023
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39. Market Analysis of MEC-Assisted Beyond 5G Ecosystem

Author

Nakazato, Jin, Nakamura, Makoto, Yu, Tao, Li, Zongdian, Maruta, Kazuki, Tran, Gia Khanh, and Sakaguchi, Kei

Subjects
CAPEX, Computer science, Multi-Access Edge Computing, 5G and beyond, heterogeneous cellular networks, social maximization revenue model, Cloud computing, 02 engineering and technology, 0203 mechanical engineering, investment strategy, 5G mobile communication, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Edge computing, mobile traffic demand, MEC 5G cellular network, Quality of service, General Engineering, Cellular networks, 020302 automobile design & engineering, Computational modeling, OPEX, Telecom Operator, Backhaul (telecommunications), Heterogeneous Networks, backhaul owner, Cellular network, Telecommunications, Mobile edge computing, Business Model, telecom operators, lcsh:TK1-9971, wireless cellular networks, cellular radio, General Computer Science, Numerical models, cloud owner, Revenue, backhaul capacity, Ecosystems, telecommunication traffic, Computer architecture, Microprocessors, Service (business), ecosystem, business.industry, 020206 networking & telecommunications, investment, multiaccess edge computing, ultralow end-to-end latency, cloud ownercess edge computing, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, 5G, traffic load
Abstract

The quality-of-service (QoS)/quality-of-experience (QoE) demands of mobile services are soaring and have overwhelmed the obsolescent capability of 3G and 4G cellular networks. The emerging 5G networks will bring an unprecedented promotion in transmission data rates. However, the satisfaction of some service requirements is still in dilemma, especially the end-to-end (E2E) latency which varies in different applications. Multi-access edge computing (MEC), a promising technology in 5G cellular networks, can provide ultra-low E2E latency and reduce traffic load on mobile backhaul networks. The potential benefits of MEC for 5G and beyond services have been explored by preliminary studies. What remains is the uncertainty of revenue from the investment of MEC which will shake operators’ decisions about whether and how to deploy MEC in cellular networks. In this light, this paper designs a MEC-assisted 5G and beyond ecosystem inclusive of three players: private (local) telecom operators, backhaul, and cloud service owners. We propose a revenue maximization model for private (local) telecom operators and cloud service owners to minimize the cost from the end-user perspective while satisfying the latency requirement. The derived model indicates that two players’ revenues can be maximized by optimizing MEC resources and backhaul capacity. The game-theoretic analyses also reveal the optimized hybrid strategy of MEC and cloud for efficient mobile traffic management.

Published
2021

42. Design of MEC 5G Cellular Networks: Viewpoints from Telecom Operators and Backhaul Owners

Author

Nakazato, Jin, Nakamura, Makoto, Yu, Tao, Li, Zongdian, Tran, Gia Khanh, and Sakaguchi, Kei

Subjects
cellular radio, Investment strategy, Computer science, Numerical models, Multi-Access Edge Computing, social maximization revenue model, Cloud computing, Revenue, backhaul capacity, investment strategy, 5G mobile communication, telecommunication traffic, Computer architecture, Microprocessors, Edge computing, mobile traffic demand, MEC 5G cellular network, business.industry, Cellular networks, investment, multiaccess edge computing, ultralow end-to-end latency, Telecom Operator, Backhaul (telecommunications), Revenue model, Heterogeneous Networks, backhaul owner, Cellular network, Telecommunications, Business Model, business, telecom operators, wireless cellular networks, 5G, traffic load, Computer network
Abstract

Recently, the mobile traffic demand is increasing due to the drastic growth in the number of connected devices and smart services utilizing wireless cellular networks. In order to deal with this tough challenge, a key technology in 5G cellular networks, Multi-Access Edge Computing (MEC) which can provide ultra-low end-to-end latency, significant reduction of traffic load on backhaul, etc., has come into sight. The potential benefits of MEC in 5G and beyond have been revealed by plenty of state-of-the-art works. However, it leaves a difficult problem for the operators, which is to determine whether and how to deploy MEC in cellular networks due to the uncertainty of feedback from the investment on MEC. Although, there were a few works studying on the optimization of the number of MEC from the viewpoint of telecom operators, their contribution focus only on telecom operators rather than taking other operators (backhaul owners, Cloud owners, etc.) into account. In this paper, we propose a social maximization revenue model with the investment strategy for the telecom operators who decide the number of MEC and the backhaul owner who lease the backhaul capacity. The numerical results indicate that the optimal number of MEC and backhaul capacity that maximize the two players' profit is the same. Hence, it turns out that the advantage of MEC can be highlighted by using both Cloud and edge resource in parallel rather than processing all traffic on the MEC side.

Published
2020

44. Design of MEC 5G and Beyond Cellular Networks: Viewpoint from Local Telecom Operators and Cloud Owners

Author

Nakazato, Jin, Li, Zongdian, Maruta, Kazuki, and Sakaguchi, Kei

Abstract

本格的な商用サービス開始が始まった5Gに関して,自治体等が5Gネットワークを活用するローカル5Gの実用化研究が行われている.さらにEnd-to-End(E2E)での伝送遅延を担保しつつバックホール側へのトラフィック負荷を軽減可能なMulti-Access Edge Computing(MEC)を導入する提案がされている.しかし,ローカル5Gを所有する事業者(以下,プライベート通信事業者)がMEC導入により投資収益効果が得られるかについては数値解析を根拠とした検討が行われていない.これまで筆者らは,MEC 導入を加速させるべく,プライベート通信事業者の観点に絞り,投資収益が最大となる MEC 数の敷設数に関して検討を行ってきた.本稿では,Beyond 5G(B5G)におけるプライベート通信事業者とクラウド事業者の両事業者について投資収益の目的関数をそれぞれ設定し,多目的最適化問題において両事業者の収益が最大となる MEC数とバックホール容量について検討する.このとき, E2E伝送遅延の制約条件下においてコストの最小化を行い,MECあるいはクラウドリソースを最適に選択する.数値解析により,両事業者の収益が最大となる MEC 数とバックホール容量について解析結果を報告する., The 5G networks will bring an unprecedented promotion in transmission data rates. However, the satisfaction of some service requirements is still in dilemma, especially the end-to-end (E2E) latency which varies in different applications. Multi-access edge computing (MEC), a promising technology in 5G cellular networks, can provide ultra-low E2E latency and reduce traffic load on mobile backhaul networks. The potential benefits of MEC have been explored by preliminary studies. In beyond and 5G (B5G) era, what remains is the uncertainty of revenue from the investment of MEC which will shake operators' decisions about whether and how to deploy MEC in cellular networks. In this light, this paper designs a MEC-assisted B5G ecosystem inclusive of three players: private (local) telecom operators, backhaul, and cloud service owners. We propose a revenue maximization model for private (local) telecom operators and cloud service owners to minimize the cost from the end-user perspective while satisfying the latency requirement.

Published
2021

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