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Your search keyword '"Huang, Yewei"' showing total 182 results
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182 results on '"Huang, Yewei"'

1. MAC: Graph Sparsification by Maximizing Algebraic Connectivity

Author

Doherty, Kevin, Papalia, Alan, Huang, Yewei, Rosen, David, Englot, Brendan, and Leonard, John

Subjects
Computer Science - Robotics
Abstract

Simultaneous localization and mapping (SLAM) is a critical capability in autonomous navigation, but memory and computational limits make long-term application of common SLAM techniques impractical; a robot must be able to determine what information should be retained and what can safely be forgotten. In graph-based SLAM, the number of edges (measurements) in a pose graph determines both the memory requirements of storing a robot's observations and the computational expense of algorithms deployed for performing state estimation using those observations, both of which can grow unbounded during long-term navigation. Motivated by these challenges, we propose a new general purpose approach to sparsify graphs in a manner that maximizes algebraic connectivity, a key spectral property of graphs which has been shown to control the estimation error of pose graph SLAM solutions. Our algorithm, MAC (for maximizing algebraic connectivity), is simple and computationally inexpensive, and admits formal post hoc performance guarantees on the quality of the solution that it provides. In application to the problem of pose-graph SLAM, we show on several benchmark datasets that our approach quickly produces high-quality sparsification results which retain the connectivity of the graph and, in turn, the quality of corresponding SLAM solutions., Comment: 17 pages, 5 figures. Submitted to IEEE Transactions on Robotics. arXiv admin note: substantial text overlap with arXiv:2203.13897

Published
2024

2. Multi-Robot Autonomous Exploration and Mapping Under Localization Uncertainty with Expectation-Maximization

Author

Huang, Yewei, Lin, Xi, and Englot, Brendan

Subjects
Computer Science - Robotics
Abstract

We propose an autonomous exploration algorithm designed for decentralized multi-robot teams, which takes into account map and localization uncertainties of range-sensing mobile robots. Virtual landmarks are used to quantify the combined impact of process noise and sensor noise on map uncertainty. Additionally, we employ an iterative expectation-maximization inspired algorithm to assess the potential outcomes of both a local robot's and its neighbors' next-step actions. To evaluate the effectiveness of our framework, we conduct a comparative analysis with state-of-the-art algorithms. The results of our experiments show the proposed algorithm's capacity to strike a balance between curbing map uncertainty and achieving efficient task allocation among robots.

Published
2024

3. Decentralized Multi-Robot Navigation for Autonomous Surface Vehicles with Distributional Reinforcement Learning

Author

Lin, Xi, Huang, Yewei, Chen, Fanfei, and Englot, Brendan

Subjects
Computer Science - Robotics
Abstract

Collision avoidance algorithms for Autonomous Surface Vehicles (ASV) that follow the Convention on the International Regulations for Preventing Collisions at Sea (COLREGs) have been proposed in recent years. However, it may be difficult and unsafe to follow COLREGs in congested waters, where multiple ASVs are navigating in the presence of static obstacles and strong currents, due to the complex interactions. To address this problem, we propose a decentralized multi-ASV collision avoidance policy based on Distributional Reinforcement Learning, which considers the interactions among ASVs as well as with static obstacles and current flows. We evaluate the performance of the proposed Distributional RL based policy against a traditional RL-based policy and two classical methods, Artificial Potential Fields (APF) and Reciprocal Velocity Obstacles (RVO), in simulation experiments, which show that the proposed policy achieves superior performance in navigation safety, while requiring minimal travel time and energy. A variant of our framework that automatically adapts its risk sensitivity is also demonstrated to improve ASV safety in highly congested environments., Comment: The 2024 IEEE International Conference on Robotics and Automation (ICRA 2024)

Published
2024

4. DRACo-SLAM: Distributed Robust Acoustic Communication-efficient SLAM for Imaging Sonar Equipped Underwater Robot Teams

Author

McConnell, John, Huang, Yewei, Szenher, Paul, Collado-Gonzalez, Ivana, and Englot, Brendan

Subjects
Computer Science - Robotics
Abstract

An essential task for a multi-robot system is generating a common understanding of the environment and relative poses between robots. Cooperative tasks can be executed only when a vehicle has knowledge of its own state and the states of the team members. However, this has primarily been achieved with direct rendezvous between underwater robots, via inter-robot ranging. We propose a novel distributed multi-robot simultaneous localization and mapping (SLAM) framework for underwater robots using imaging sonar-based perception. By passing only scene descriptors between robots, we do not need to pass raw sensor data unless there is a likelihood of inter-robot loop closure. We utilize pairwise consistent measurement set maximization (PCM), making our system robust to erroneous loop closures. The functionality of our system is demonstrated using two real-world datasets, one with three robots and another with two robots. We show that our system effectively estimates the trajectories of the multi-robot system and keeps the bandwidth requirements of inter-robot communication low. To our knowledge, this paper describes the first instance of multi-robot SLAM using real imaging sonar data (which we implement offline, using simulated communication). Code link: https://github.com/jake3991/DRACo-SLAM., Comment: To appear at IROS 2022 in Kyoto, Japan

Published
2022

6. Virtual Maps for Autonomous Exploration of Cluttered Underwater Environments

Author

Wang, Jinkun, Chen, Fanfei, Huang, Yewei, McConnell, John, Shan, Tixiao, and Englot, Brendan

Subjects
Computer Science - Robotics
Abstract

We consider the problem of autonomous mobile robot exploration in an unknown environment, taking into account a robot's coverage rate, map uncertainty, and state estimation uncertainty. This paper presents a novel exploration framework for underwater robots operating in cluttered environments, built upon simultaneous localization and mapping (SLAM) with imaging sonar. The proposed system comprises path generation, place recognition forecasting, belief propagation and utility evaluation using a virtual map, which estimates the uncertainty associated with map cells throughout a robot's workspace. We evaluate the performance of this framework in simulated experiments, showing that our algorithm maintains a high coverage rate during exploration while also maintaining low mapping and localization error. The real-world applicability of our framework is also demonstrated on an underwater remotely operated vehicle (ROV) exploring a harbor environment., Comment: Preprint; Accepted for publication in the IEEE Journal of Oceanic Engineering

Published
2022

8. Zero-Shot Reinforcement Learning on Graphs for Autonomous Exploration Under Uncertainty

Author

Chen, Fanfei, Szenher, Paul, Huang, Yewei, Wang, Jinkun, Shan, Tixiao, Bai, Shi, and Englot, Brendan

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

This paper studies the problem of autonomous exploration under localization uncertainty for a mobile robot with 3D range sensing. We present a framework for self-learning a high-performance exploration policy in a single simulation environment, and transferring it to other environments, which may be physical or virtual. Recent work in transfer learning achieves encouraging performance by domain adaptation and domain randomization to expose an agent to scenarios that fill the inherent gaps in sim2sim and sim2real approaches. However, it is inefficient to train an agent in environments with randomized conditions to learn the important features of its current state. An agent can use domain knowledge provided by human experts to learn efficiently. We propose a novel approach that uses graph neural networks in conjunction with deep reinforcement learning, enabling decision-making over graphs containing relevant exploration information provided by human experts to predict a robot's optimal sensing action in belief space. The policy, which is trained only in a single simulation environment, offers a real-time, scalable, and transferable decision-making strategy, resulting in zero-shot transfer to other simulation environments and even real-world environments.

Published
2021

9. Autonomous Exploration Under Uncertainty via Deep Reinforcement Learning on Graphs

Author

Chen, Fanfei, Martin, John D., Huang, Yewei, Wang, Jinkun, and Englot, Brendan

Subjects
Computer Science - Robotics, Computer Science - Machine Learning
Abstract

We consider an autonomous exploration problem in which a range-sensing mobile robot is tasked with accurately mapping the landmarks in an a priori unknown environment efficiently in real-time; it must choose sensing actions that both curb localization uncertainty and achieve information gain. For this problem, belief space planning methods that forward-simulate robot sensing and estimation may often fail in real-time implementation, scaling poorly with increasing size of the state, belief and action spaces. We propose a novel approach that uses graph neural networks (GNNs) in conjunction with deep reinforcement learning (DRL), enabling decision-making over graphs containing exploration information to predict a robot's optimal sensing action in belief space. The policy, which is trained in different random environments without human intervention, offers a real-time, scalable decision-making process whose high-performance exploratory sensing actions yield accurate maps and high rates of information gain.

Published
2020

11. Vision-based Semantic Mapping and Localization for Autonomous Indoor Parking

Author

Huang, Yewei, Zhao, Junqiao, He, Xudong, Zhang, Shaoming, and Feng, Tiantian

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

In this paper, we proposed a novel and practical solution for the real-time indoor localization of autonomous driving in parking lots. High-level landmarks, the parking slots, are extracted and enriched with labels to avoid the aliasing of low-level visual features. We then proposed a robust method for detecting incorrect data associations between parking slots and further extended the optimization framework by dynamically eliminating suboptimal data associations. Visual fiducial markers are introduced to improve the overall precision. As a result, a semantic map of the parking lot can be established fully automatically and robustly. We experimented the performance of real-time localization based on the map using our autonomous driving platform TiEV, and the average accuracy of 0.3m track tracing can be achieved at a speed of 10kph.

Published
2018

12. Automatic Vector-based Road Structure Mapping Using Multi-beam LiDAR

Author

He, Xudong, Zhao, Junqiao, Sun, Lu, Huang, Yewei, Zhang, Xinglian, Li, Jun, and Ye, Chen

Subjects
Computer Science - Robotics
Abstract

In this paper, we studied a SLAM method for vector-based road structure mapping using multi-beam LiDAR. We propose to use the polyline as the primary mapping element instead of grid cell or point cloud, because the vector-based representation is precise and lightweight, and it can directly generate vector-based High-Definition (HD) driving map as demanded by autonomous driving systems. We explored: 1) the extraction and vectorization of road structures based on local probabilistic fusion. 2) the efficient vector-based matching between frames of road structures. 3) the loop closure and optimization based on the pose-graph. In this study, we took a specific road structure, the road boundary, as an example. We applied the proposed matching method in three different scenes and achieved the average absolute matching error of 0.07. We further applied the mapping system to the urban road with the length of 860 meters and achieved an average global accuracy of 0.466 m without the help of high precision GPS.

Published
2018

13. TiEV: The Tongji Intelligent Electric Vehicle in the Intelligent Vehicle Future Challenge of China

Author

Zhao, Junqiao, Ye, Chen, Wu, Yan, Guan, Linting, Cai, Lewen, Sun, Lu, Yang, Tao, He, Xudong, Li, Jun, Ding, Yongchao, Zhang, Xinglian, Wang, Xinchen, Huang, Jinlin, Zhang, Enwei, Huang, Yewei, Jiang, Wei, Zhang, Shaoming, Xiong, Lu, and Feng, Tiantian

Subjects
Computer Science - Robotics
Abstract

TiEV is an autonomous driving platform implemented by Tongji University of China. The vehicle is drive-by-wire and is fully powered by electricity. We devised the software system of TiEV from scratch, which is capable of driving the vehicle autonomously in urban paths as well as on fast express roads. We describe our whole system, especially novel modules of probabilistic perception fusion, incremental mapping, the 1st and the 2nd planning and the overall safety concern. TiEV finished 2016 and 2017 Intelligent Vehicle Future Challenge of China held at Changshu. We show our experiences on the development of autonomous vehicles and future trends.

Published
2018

15. Highly-stable, injectable, conductive hydrogel for chronic neuromodulation.

Author

Yang, Ming, Wang, Lufang, Liu, Wenliang, Li, Wenlong, Huang, Yewei, Jin, Qiaofeng, Zhang, Li, Jiang, Yuanwen, and Luo, Zhiqiang

Subjects
BRAIN-computer interfaces, CHEMICAL kinetics, LABORATORY rats, MALE models, MYOCARDIAL infarction
Abstract

Electroceuticals, through the selective modulation of peripheral nerves near target organs, are promising for treating refractory diseases. However, the small sizes and the delicate nature of these nerves present challenges in simplifying the fixation and stabilizing the electrical-coupling interface for neural electrodes. Herein, we construct a robust neural interface for fine peripheral nerves using an injectable bio-adhesive hydrogel bioelectronics. By incorporating a multifunctional molecular regulator during network formation, we optimize the injectability and conductivity of the hydrogel through fine-tuning reaction kinetics and multi-scale interactions within the conductive network. Meanwhile, the mechanical and electrical stability of the hydrogel is achieved without compromising its injectability. Minimal tissue damage along with low and stable impedance of the injectable neural interface enables chronic vagus neuromodulation for myocardial infarction therapy in the male rat model. Our highly-stable, injectable, conductive hydrogel bioelectronics are readily available to target challenging anatomical locations, paving the way for future precision bioelectronic medicine. Electroceuticals could treat refractory diseases by the selective modulation of peripheral nerves but their utility is hindered by the small sizes and the delicate nature of the nerves. Here, the authors address these issues by developing an injectable, stable, and conductive hydrogel that allows a safer and more effective treatment during chronic neuromodulation of delicate peripheral nerves. [ABSTRACT FROM AUTHOR]

Published
2024
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18. MAC: Maximizing Algebraic Connectivity for Graph Sparsification

Author

Doherty, Kevin, Papalia, Alan, Huang, Yewei, Rosen, David, Englot, Brendan, Leonard, John, Doherty, Kevin, Papalia, Alan, Huang, Yewei, Rosen, David, Englot, Brendan, and Leonard, John

Abstract

Simultaneous localization and mapping (SLAM) is a critical capability in autonomous navigation, but memory and computational limits make long-term application of common SLAM techniques impractical; a robot must be able to determine what information should be retained and what can safely be forgotten. In graph-based SLAM, the number of edges (measurements) in a pose graph determines both the memory requirements of storing a robot's observations and the computational expense of algorithms deployed for performing state estimation using those observations, both of which can grow unbounded during long-term navigation. Motivated by these challenges, we propose a new general purpose approach to sparsify graphs in a manner that maximizes algebraic connectivity, a key spectral property of graphs which has been shown to control the estimation error of pose graph SLAM solutions. Our algorithm, MAC (for maximizing algebraic connectivity), is simple and computationally inexpensive, and admits formal post hoc performance guarantees on the quality of the solution that it provides. In application to the problem of pose-graph SLAM, we show on several benchmark datasets that our approach quickly produces high-quality sparsification results which retain the connectivity of the graph and, in turn, the quality of corresponding SLAM solutions., Comment: 17 pages, 5 figures. Submitted to IEEE Transactions on Robotics. arXiv admin note: substantial text overlap with arXiv:2203.13897

Published
2024

21. 新一代火星大气模式GoPlanet-Mars V1的研制

Author

Dong, Li, primary, Pu, Ye, additional, Li, Yiyuan, additional, Liu, Hongbo, additional, Liu, Juanjuan, additional, Deng, Shiya, additional, Huang, Yewei, additional, Liu, Mingyu, additional, Liu, Shuai, additional, and Wang, Bin, additional

Published
2023
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22. AIMED: AI-Mediated Exploration of Design: An Experience Report

Author

Narain, Sanjai, primary, Chee, Dana, additional, Iyer, Pranav, additional, Mak, Emily, additional, Valdez, Ricardo, additional, Zhu, Manli, additional, Jha, Niraj, additional, Fisac, Jaime, additional, Hsu, Kai-Chieh, additional, Terway, Prerit, additional, Pochiraju, Kishore, additional, Englot, Brendan, additional, Pitz, Emil, additional, Rooney, Sean, additional, and Huang, Yewei, additional

Published
2023
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39. Proliferation of MDA-MB-231 can be suppressed by dimeric-epigallocatechin gallate through competitive inhibition of amphiregulin-epidermal growth factor receptor signaling

Author

Huang, Yewei, primary, Zhang, Xiaojuan, additional, Pang, Qianqian, additional, Zhu, Qiangqiang, additional, Liang, Qingqing, additional, Zi, Chengting, additional, Zhang, Dongying, additional, Xiang, Zemin, additional, Wang, Xuanjun, additional, and Sheng, Jun, additional

Published
2021
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