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1. Semantic2D: A Semantic Dataset for 2D Lidar Semantic Segmentation

Author

Xie, Zhanteng and Dames, Philip

Subjects
Computer Science - Robotics
Abstract

This paper presents a 2D lidar semantic segmentation dataset to enhance the semantic scene understanding for mobile robots in different indoor robotics applications. While most existing lidar semantic datasets focus on 3D lidar sensors and autonomous driving scenarios, the proposed 2D lidar semantic dataset is the first public dataset for 2D lidar sensors and mobile robots. It contains data collected in six different indoor environments and has nine categories of typical objects in indoor environments. A novel semi-automatic semantic labeling framework is proposed to provide point-wise annotation for the dataset with minimal human effort. Based on this 2D lidar dataset, a hardware-friendly stochastic semantic segmentation benchmark is proposed to enable 2D lidar sensors to have semantic scene understanding capabilities. A series of segmentation tests are performed to demonstrate that the proposed learning-based segmentation benchmark can achieve more accurate and richer segmentation for each lidar point compared to traditional geometry-based extraction algorithms.

Published
2024

2. Speech-Guided Sequential Planning for Autonomous Navigation using Large Language Model Meta AI 3 (Llama3)

Author

Srivastava, Alkesh K. and Dames, Philip

Subjects
Computer Science - Robotics
Abstract

In social robotics, a pivotal focus is enabling robots to engage with humans in a more natural and seamless manner. The emergence of advanced large language models (LLMs) such as Generative Pre-trained Transformers (GPTs) and autoregressive models like Large Language Model Meta AI (Llamas) has driven significant advancements in integrating natural language understanding capabilities into social robots. This paper presents a system for speech-guided sequential planning in autonomous navigation, utilizing Llama3 and the Robot Operating System~(ROS). The proposed system involves using Llama3 to interpret voice commands, extracting essential details through parsing, and decoding these commands into sequential actions for tasks. Such sequential planning is essential in various domains, particularly in the pickup and delivery of an object. Once a sequential navigation task is evaluated, we employ DRL-VO, a learning-based control policy that allows a robot to autonomously navigate through social spaces with static infrastructure and (crowds of) people. We demonstrate the effectiveness of the system in simulation experiment using Turtlebot 2 in ROS1 and Turtlebot 3 in ROS2. We conduct hardware trials using a Clearpath Robotics Jackal UGV, highlighting its potential for real-world deployment in scenarios requiring flexible and interactive robotic behaviors.

Published
2024

3. SCOPE: Stochastic Cartographic Occupancy Prediction Engine for Uncertainty-Aware Dynamic Navigation

Author

Xie, Zhanteng and Dames, Philip

Subjects
Computer Science - Robotics
Abstract

This article presents a family of Stochastic Cartographic Occupancy Prediction Engines (SCOPEs) that enable mobile robots to predict the future states of complex dynamic environments. They do this by accounting for the motion of the robot itself, the motion of dynamic objects, and the geometry of static objects in the scene, and they generate a range of possible future states of the environment. These prediction algorithms are software-optimized for real-time performance for navigation in crowded dynamic scenes, achieving 10 times faster inference speed and 3 times less memory usage than the original engines. Three simulated and real-world datasets collected by different robot models are used to demonstrate that these proposed prediction algorithms are able to achieve more accurate and robust stochastic prediction performance than other algorithms. Furthermore, a series of simulation and hardware navigation experiments demonstrate that the proposed predictive uncertainty-aware navigation framework with these stochastic prediction engines is able to improve the safe navigation performance of current state-of-the-art model- and learning-based control policies.

Published
2024

4. Towards Predicting Collective Performance in Multi-Robot Teams

Author

Xin, Pujie, Xie, Zhanteng, and Dames, Philip

Subjects
Computer Science - Robotics
Abstract

The increased deployment of multi-robot systems (MRS) in various fields has led to the need for analysis of system-level performance. However, creating consistent metrics for MRS is challenging due to the wide range of system and environmental factors, such as team size and environment size. This paper presents a new analytical framework for MRS based on dimensionless variable analysis, a mathematical technique typically used to simplify complex physical systems. This approach effectively condenses the complex parameters influencing MRS performance into a manageable set of dimensionless variables. We form dimensionless variables which encapsulate key parameters of the robot team and task. Then we use these dimensionless variables to fit a parametric model of team performance. Our model successfully identifies critical performance determinants and their interdependencies, providing insight for MRS design and optimization. The application of dimensionless variable analysis to MRS offers a promising method for MRS analysis that effectively reduces complexity, enhances comprehension of system behaviors, and informs the design and management of future MRS deployments.

Published
2024

5. Splat-Nav: Safe Real-Time Robot Navigation in Gaussian Splatting Maps

Author

Chen, Timothy, Shorinwa, Ola, Bruno, Joseph, Yu, Javier, Zeng, Weijia, Nagami, Keiko, Dames, Philip, and Schwager, Mac

Subjects
Computer Science - Robotics
Abstract

We present Splat-Nav, a real-time navigation pipeline designed to work with environment representations generated by Gaussian Splatting (GSplat), a popular emerging 3D scene representation from computer vision. Splat-Nav consists of two components: 1) Splat-Plan, a safe planning module, and 2) Splat-Loc, a robust pose estimation module. Splat-Plan builds a safe-by-construction polytope corridor through the map based on mathematically rigorous collision constraints and then constructs a B\'ezier curve trajectory through this corridor. Splat-Loc provides a robust state estimation module, leveraging the point-cloud representation inherent in GSplat scenes for global pose initialization, in the absence of prior knowledge, and recursive real-time pose localization, given only RGB images. The most compute-intensive procedures in our navigation pipeline, such as the computation of the B\'ezier trajectories and the pose optimization problem run primarily on the CPU, freeing up GPU resources for GPU-intensive tasks, such as online training of Gaussian Splats. We demonstrate the safety and robustness of our pipeline in both simulation and hardware experiments, where we show online re-planning at 5 Hz and pose estimation at about 25 Hz, an order of magnitude faster than Neural Radiance Field (NeRF)-based navigation methods, thereby enabling real-time navigation.

Published
2024

6. Distributed Multi-Robot Multi-Target Tracking Using Heterogeneous Limited-Range Sensors

Author

Chen, Jun, Abugurain, Mohammed, Dames, Philip, and Park, Shinkyu

Subjects
Computer Science - Robotics
Abstract

This paper presents a cooperative multi-robot multi-target tracking framework aimed at enhancing the efficiency of the heterogeneous sensor network and, consequently, improving overall target tracking accuracy. The concept of normalized unused sensing capacity is introduced to quantify the information a sensor is currently gathering relative to its theoretical maximum. This measurement can be computed using entirely local information and is applicable to various sensor models, distinguishing it from previous literature on the subject. It is then utilized to develop a distributed coverage control strategy for a heterogeneous sensor network, adaptively balancing the workload based on each sensor's current unused capacity. The algorithm is validated through a series of ROS and MATLAB simulations, demonstrating superior results compared to standard approaches that do not account for heterogeneity or current usage rates.

Published
2023

7. Comparing Stochastic Optimization Methods for Multi-robot, Multi-target Tracking

Author

Xin, Pujie, Dames, Philip, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Bourgeois, Julien, editor, Paik, Jamie, editor, Piranda, Benoît, editor, Werfel, Justin, editor, Hauert, Sabine, editor, Pierson, Alyssa, editor, Hamann, Heiko, editor, Lam, Tin Lun, editor, Matsuno, Fumitoshi, editor, Mehr, Negar, editor, and Makhoul, Abdallah, editor

Published
2024
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8. Distributed Multiple Hypothesis Tracker for Mobile Sensor Networks

Author

Xin, Pujie, Dames, Philip, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Bourgeois, Julien, editor, Paik, Jamie, editor, Piranda, Benoît, editor, Werfel, Justin, editor, Hauert, Sabine, editor, Pierson, Alyssa, editor, Hamann, Heiko, editor, Lam, Tin Lun, editor, Matsuno, Fumitoshi, editor, Mehr, Negar, editor, and Makhoul, Abdallah, editor

Published
2024
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9. Distributed Multi-robot Tracking of Unknown Clustered Targets with Noisy Measurements

Author

Chen, Jun, Dames, Philip, Park, Shinkyu, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Bourgeois, Julien, editor, Paik, Jamie, editor, Piranda, Benoît, editor, Werfel, Justin, editor, Hauert, Sabine, editor, Pierson, Alyssa, editor, Hamann, Heiko, editor, Lam, Tin Lun, editor, Matsuno, Fumitoshi, editor, Mehr, Negar, editor, and Makhoul, Abdallah, editor

Published
2024
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10. DRL-VO: Learning to Navigate Through Crowded Dynamic Scenes Using Velocity Obstacles

Author

Xie, Zhanteng and Dames, Philip

Subjects
Computer Science - Robotics
Abstract

This paper proposes a novel learning-based control policy with strong generalizability to new environments that enables a mobile robot to navigate autonomously through spaces filled with both static obstacles and dense crowds of pedestrians. The policy uses a unique combination of input data to generate the desired steering angle and forward velocity: a short history of lidar data, kinematic data about nearby pedestrians, and a sub-goal point. The policy is trained in a reinforcement learning setting using a reward function that contains a novel term based on velocity obstacles to guide the robot to actively avoid pedestrians and move towards the goal. Through a series of 3D simulated experiments with up to 55 pedestrians, this control policy is able to achieve a better balance between collision avoidance and speed (i.e., higher success rate and faster average speed) than state-of-the-art model-based and learning-based policies, and it also generalizes better to different crowd sizes and unseen environments. An extensive series of hardware experiments demonstrate the ability of this policy to directly work in different real-world environments with different crowd sizes with zero retraining. Furthermore, a series of simulated and hardware experiments show that the control policy also works in highly constrained static environments on a different robot platform without any additional training. Lastly, several important lessons that can be applied to other robot learning systems are summarized. Multimedia demonstrations are available at https://www.youtube.com/watch?v=KneELRT8GzU&list=PLouWbAcP4zIvPgaARrV223lf2eiSR-eSS., Comment: Accepted by IEEE Transactions on Robotics (T-RO), 2023

Published
2023
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14. Stochastic Occupancy Grid Map Prediction in Dynamic Scenes

Author

Xie, Zhanteng and Dames, Philip

Subjects
Computer Science - Robotics
Abstract

This paper presents two variations of a novel stochastic prediction algorithm that enables mobile robots to accurately and robustly predict the future state of complex dynamic scenes. The proposed algorithm uses a variational autoencoder to predict a range of possible future states of the environment. The algorithm takes full advantage of the motion of the robot itself, the motion of dynamic objects, and the geometry of static objects in the scene to improve prediction accuracy. Three simulated and real-world datasets collected by different robot models are used to demonstrate that the proposed algorithm is able to achieve more accurate and robust prediction performance than other prediction algorithms. Furthermore, a predictive uncertainty-aware planner is proposed to demonstrate the effectiveness of the proposed predictor in simulation and real-world navigation experiments. Implementations are open source at https://github.com/TempleRAIL/SOGMP., Comment: Accepted by 7th Annual Conference on Robot Learning (CoRL), 2023

Published
2022

15. Autonomous Ground Navigation in Highly Constrained Spaces: Lessons learned from The BARN Challenge at ICRA 2022

Author

Xiao, Xuesu, Xu, Zifan, Wang, Zizhao, Song, Yunlong, Warnell, Garrett, Stone, Peter, Zhang, Tingnan, Ravi, Shravan, Wang, Gary, Karnan, Haresh, Biswas, Joydeep, Mohammad, Nicholas, Bramblett, Lauren, Peddi, Rahul, Bezzo, Nicola, Xie, Zhanteng, and Dames, Philip

Subjects
Computer Science - Robotics
Abstract

The BARN (Benchmark Autonomous Robot Navigation) Challenge took place at the 2022 IEEE International Conference on Robotics and Automation (ICRA 2022) in Philadelphia, PA. The aim of the challenge was to evaluate state-of-the-art autonomous ground navigation systems for moving robots through highly constrained environments in a safe and efficient manner. Specifically, the task was to navigate a standardized, differential-drive ground robot from a predefined start location to a goal location as quickly as possible without colliding with any obstacles, both in simulation and in the real world. Five teams from all over the world participated in the qualifying simulation competition, three of which were invited to compete with each other at a set of physical obstacle courses at the conference center in Philadelphia. The competition results suggest that autonomous ground navigation in highly constrained spaces, despite seeming ostensibly simple even for experienced roboticists, is actually far from being a solved problem. In this article, we discuss the challenge, the approaches used by the top three winning teams, and lessons learned to direct future research.

Published
2022

17. Multi-class Target Tracking Using the Semantic PHD Filter

Author

Chen, Jun, Dames, Philip, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Asfour, Tamim, editor, Yoshida, Eiichi, editor, and Christensen, Henrik, editor

Published
2022
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18. Experimental Characterization of a Bearing-only Sensor for Use With the PHD Filter

Author

Dames, Philip and Kumar, Vijay

Subjects
Computer Science - Robotics
Abstract

This report outlines the procedure and results of an experiment to characterize a bearing-only sensor for use with PHD filter. The resulting detection, measurement, and clutter models are used for hardware and simulated experiments with a team of mobile robots autonomously seeking an unknown number of objects of interest in an office environment.

Published
2015

19. Artificial Intelligence for Climate Smart Forestry: A Forward Looking Vision

Author

Luo, Feng, primary, Liu, Ling, additional, Wang, G. Geoff, additional, Kumar, Vijay, additional, Ashton, Mark S., additional, Abernethy, Jacob, additional, Afghah, Fatemeh, additional, Browning, Matthew H. E. M, additional, Coyle, David, additional, Dames, Philip, additional, O'Halloran, Tom, additional, Hays, James, additional, Heisl, Patrick, additional, Jiang, Chenfanfu, additional, Khanal, Puskar, additional, Krovi, Venkat Narayan, additional, Kuebbing, Sara, additional, Li, Nianyi, additional, Liang, JingJing, additional, Liu, Ninghao, additional, McNulty, Steve, additional, Oswalt, Christopher M., additional, Pederson, Neil, additional, Terzopoulos, Demetri, additional, Woodall, Christopher W., additional, Wu, Yongkai, additional, Yang, Jian, additional, Yang, Yin, additional, and Zhao, Liang, additional

Published
2023
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21. Technical Report: Cooperative Multi-Target Localization With Noisy Sensors

Author

Dames, Philip and Kumar, Vijay

Subjects
Computer Science - Robotics, Computer Science - Multiagent Systems
Abstract

This technical report is an extended version of the paper 'Cooperative Multi-Target Localization With Noisy Sensors' accepted to the 2013 IEEE International Conference on Robotics and Automation (ICRA). This paper addresses the task of searching for an unknown number of static targets within a known obstacle map using a team of mobile robots equipped with noisy, limited field-of-view sensors. Such sensors may fail to detect a subset of the visible targets or return false positive detections. These measurement sets are used to localize the targets using the Probability Hypothesis Density, or PHD, filter. Robots communicate with each other on a local peer-to-peer basis and with a server or the cloud via access points, exchanging measurements and poses to update their belief about the targets and plan future actions. The server provides a mechanism to collect and synthesize information from all robots and to share the global, albeit time-delayed, belief state to robots near access points. We design a decentralized control scheme that exploits this communication architecture and the PHD representation of the belief state. Specifically, robots move to maximize mutual information between the target set and measurements, both self-collected and those available by accessing the server, balancing local exploration with sharing knowledge across the team. Furthermore, robots coordinate their actions with other robots exploring the same local region of the environment., Comment: Extended version of paper accepted to 2013 IEEE International Conference on Robotics and Automation (ICRA)

Published
2013
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26. Autonomous Ground Navigation in Highly Constrained Spaces: Lessons Learned From the Benchmark Autonomous Robot Navigation Challenge at ICRA 2022 [Competitions]

Author

Xiao, Xuesu, primary, Xu, Zifan, additional, Wang, Zizhao, additional, Song, Yunlong, additional, Warnell, Garrett, additional, Stone, Peter, additional, Zhang, Tingnan, additional, Ravi, Shravan, additional, Wang, Gary, additional, Karnan, Haresh, additional, Biswas, Joydeep, additional, Mohammad, Nicholas, additional, Bramblett, Lauren, additional, Peddi, Rahul, additional, Bezzo, Nicola, additional, Xie, Zhanteng, additional, and Dames, Philip, additional

Published
2022
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42. A survey on aerial swarm robotics

Author

Chung, Soon-Jo, Paranjape, Aditya Avinash, Dames, Philip, Shen, Shaojie, Kumar, Vijay, Chung, Soon-Jo, Paranjape, Aditya Avinash, Dames, Philip, Shen, Shaojie, and Kumar, Vijay

Abstract

The use of aerial swarms to solve real-world problems has been increasing steadily, accompanied by falling prices and improving performance of communication, sensing, and processing hardware. The commoditization of hardware has reduced unit costs, thereby lowering the barriers to entry to the field of aerial swarm robotics. A key enabling technology for swarms is the family of algorithms that allow the individual members of the swarm to communicate and allocate tasks amongst themselves, plan their trajectories, and coordinate their flight in such a way that the overall objectives of the swarm are achieved efficiently. These algorithms, often organized in a hierarchical fashion, endow the swarm with autonomy at every level, and the role of a human operator can be reduced, in principle, to interactions at a higher level without direct intervention. This technology depends on the clever and innovative application of theoretical tools from control and estimation. This paper reviews the state of the art of these theoretical tools, specifically focusing on how they have been developed for, and applied to, aerial swarms. Aerial swarms differ from swarms of ground-based vehicles in two respects: they operate in a three-dimensional space and the dynamics of individual vehicles adds an extra layer of complexity. We review dynamic modeling and conditions for stability and controllability that are essential in order to achieve cooperative flight and distributed sensing. The main sections of this paper focus on major results covering trajectory generation, task allocation, adversarial control, distributed sensing, monitoring, and mapping. Wherever possible, we indicate how the physics and subsystem technologies of aerial robots are brought to bear on these individual areas.

Published
2018

45. Active Magnetic Anomaly Detection Using Multiple Micro Aerial Vehicles

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Rus, Daniela L, Dames, Philip M., Schwager, Mac, Kumar, Vijay, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Rus, Daniela L, Dames, Philip M., Schwager, Mac, and Kumar, Vijay

Abstract

Magnetic anomaly detection (MAD) is an important problem in applications ranging from geological surveillance to military reconnaissance. MAD sensors detect local disturbances in the magnetic field, which can be used to detect the existence of and to estimate the position of buried, hidden, or submerged objects, such as ore deposits or mines. These sensors may experience false positive and false negative detections and, without prior knowledge of the targets, can only determine proximity to a target. The uncertainty in the sensors, coupled with a lack of knowledge of even the existence of targets, makes the estimation and control problems challenging. We utilize a hierarchical decomposition of the environment, coupled with an estimation algorithm based on random finite sets, to determine the number of and the locations of targets in the environment. The small team of robots follow the gradient of mutual information between the estimated set of targets and the future measurements, locally maximizing the rate of information gain. We present experimental results of a team of quadrotor micro aerial vehicles discovering and localizing an unknown number of permanent magnets., United States. Office of Naval Research (Grant N00014-07-1-0829), United States. Office of Naval Research (Grant N00014-09-1-1051), United States. Office of Naval Research (Grant N00014-09-1-1031), United States. Army Research Office (Grant W911NF-13-1-0350), National Science Foundation (U.S.) (Grant IIS-1426840)

Published
2017

48. Multi-robot active information gathering using random finite sets

Author

Dames, Philip M and Dames, Philip M

Abstract

Many tasks in the modern world involve collecting information, such as infrastructure inspection, security and surveillance, environmental monitoring, and search and rescue. All of these tasks involve searching an environment to detect, localize, and track objects of interest, such as damage to roadways, suspicious packages, plant species, or victims of a natural disaster. In any of these tasks the number of objects of interest is often not known at the onset of exploration. Teams of robots can automate these often dull, dirty, or dangerous tasks to decrease costs and improve speed and safety. This dissertation addresses the problem of automating data collection processes, so that a team of mobile sensor platforms is able to explore an environment to determine the number of objects of interest and their locations. In real-world scenarios, robots may fail to detect objects within the field of view, receive false positive measurements to clutter objects, and be unable to disambiguate true objects. This makes data association, i.e., matching individual measurements to targets, difficult. To account for this, we utilize filtering algorithms based on random finite sets to simultaneously estimate the number of objects and their locations within the environment without the need to explicitly consider data association. Using the resulting estimates they receive, robots choose actions that maximize the mutual information between the set of targets and the binary events of receiving no detections. This effectively hedges against uninformative actions and leads to a closed form equation to compute mutual information, allowing the robot team to plan over a long time horizon. The robots either communicate with a central agent, which performs the estimation and control computations, or act in a decentralized manner. Our extensive hardware and simulated experiments validate the unified estimation and control framework, using robots with a wide variety of mobility and sensing capab

Published
2015

49. Autonomous robotic exploration using a utility function based on Rényi’s general theory of entropy.

Author

Carrillo, Henry, Dames, Philip, Kumar, Vijay, and Castellanos, José A.

Subjects
CURRENT distribution, ELECTRIC currents, ENTROPY, STATISTICAL physics, THERMODYNAMICS
Abstract

In this paper we present a novel information-theoretic utility function for selecting actions in a robot-based autonomous exploration task. The robot’s goal in an autonomous exploration task is to create a complete, high-quality map of an unknown environment as quickly as possible. This implicitly requires the robot to maintain an accurate estimate of its pose as it explores both unknown and previously observed terrain in order to correctly incorporate new information into the map. Our utility function simultaneously considers uncertainty in both the robot pose and the map in a novel way and is computed as the difference between the Shannon and the Rényi entropy of the current distribution over maps. Rényi’s entropy is a family of functions parameterized by a scalar, with Shannon’s entropy being the limit as this scalar approaches unity. We link the value of this scalar parameter to the predicted future uncertainty in the robot’s pose after taking an exploratory action. This effectively decreases the expected information gain of the action, with higher uncertainty in the robot’s pose leading to a smaller expected information gain. Our objective function allows the robot to automatically trade off between exploration and exploitation in a way that does not require manually tuning parameter values, a significant advantage over many competing methods that only use Shannon’s definition of entropy. We use simulated experiments to compare the performance of our proposed utility function to these state-of-the-art utility functions. We show that robots that use our proposed utility function generate maps with less uncertainty and fewer visible artifacts and that the robots have less uncertainty in their pose during exploration. Finally, we demonstrate that a real-world robot using our proposed utility function is able to successfully create a high-quality map of an indoor office environment. [ABSTRACT FROM AUTHOR]

Published
2018
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50. Detecting, localizing, and tracking an unknown number of moving targets using a team of mobile robots.

Author

Dames, Philip, Tokekar, Pratap, and Kumar, Vijay

Subjects
*MOBILE robots, *ROBOT motion, *STATISTICAL hypothesis testing
Abstract

Target tracking is a fundamental problem in robotics research and has been the subject of detailed studies over the years. In this paper, we generate a data-driven target model from a real-world dataset of taxi motions. This model includes target motion, appearance, and disappearance from the search area. Using this target model, we introduce a new formulation of the mobile target tracking problem based on the mathematical concept of random finite sets. This formulation allows for tracking an unknown and dynamic number of mobile targets with a team of robots. We show how to employ the probability hypothesis density filter to simultaneously estimate the number of targets and their positions. Next, we present a greedy algorithm for assigning trajectories to the robots to allow them to actively track the targets. We prove that the greedy algorithm is a two-approximation for maximizing submodular tracking objective functions. We examine two such functions: the mutual information between the estimated target positions and future measurements from the robots and a new objective that maximizes the expected number of targets detected by the robot team. We provide extensive simulation evaluations to validate the performance of our data-driven motion model and to compare the behavior and tracking performance of robots using our objective functions. [ABSTRACT FROM AUTHOR]

Published
2017
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