A Monte Carlo Algorithm for Multi-Robot Localization

Fox, Dieter; Burgard, Wolfram; Kruppa, Hannes; Thrun, Sebastian

doi:10.21236/ada363774

Cited by 15 publications

(7 citation statements)

References 55 publications

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“…Bayesian approaches to localization have been used in robotics for the noncooperative mobile single-agent case [18] and for the cooperative mobile multiagent case [49], [60], [107]. Bayesian cooperative localization for networks without mobility was investigated in [14], [108], and [109].…”

Section: Bayesian Cooperative Localizationmentioning

confidence: 99%

Cooperative Localization in Wireless Networks

2009

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Section: Bayesian Cooperative Localizationmentioning

confidence: 99%

Cooperative Localization in Wireless Networks

2009

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“…This probabilistic representation allows for a more flexible representation of environmental uncertainty. Therefore, occupancy grid maps are commonly employed in probabilistic localization for mobile robots, such as Kalman Filter localization [19], Markov localization [20] and Monte Carlo Localization [21],and also widely used in SLAM. For example, Wijaya et al [22] proposed an occupancy grid map mapping method on Hector SLAM technique, which could map the surrounding environment accurately using only lidar, as shown in Figure 4.…”

Section: Metric Mapsmentioning

confidence: 99%

Map representations for mobile robot localization

Zhang,

2024

Fourth International Conference on Mechanical Engineering, Intelligent Manufacturing, and Automation Technology (MEMAT 2023)

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Localization is a prerequisite for mobile robots to achieve path planning, autonomous navigation, and decision-making. In localization, maps provide mobile robots with the ability to perceive and model the environment, so the choice of an appropriate map representation has a significant impact on the localization effect of mobile robots. From the perspective of usage matching, this paper divides map representations for mobile robot localization into four categories based on different focuses of describing the environment, which are metric maps, feature maps, topological maps, and semantic maps. The principles, characteristics, and classic cases of these representations are also analyzed in this paper. Furthermore, the applicable working conditions of each type of map representation are summarized to provide effective guidance for mobile robot localization.

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“…The leading indicators of a phone's limited resources are its limited processing power, battery life, and storage space. As smartphone computing capability increases, complex fusion positioning techniques like simultaneous localization and mapping and Monte Carlo localization of mobile robots may eventually enter the field of smartphone‐based indoor localization [41, 42]. Fusion placement, however, can currently only use a tiny percentage of the CPU's processing time to maintain the system's smooth operation.…”

Section: Related Workmentioning

confidence: 99%

Optimal fusion‐based localization method for tracking of smartphone user in tall complex buildings

Jamil

Kim

2023

CAAI Trans on Intel Tech

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In the event of a fire breaking out or in other complicated situations, a mobile computing solution combining the Internet of Things and wearable devices can actually assist tracking solutions for rescuing and evacuating people in multistory structures. Thus, it is crucial to increase the positioning technology's accuracy. The sequential Monte Carlo (SMC) approach is used in various applications such as target tracking and intelligent surveillance, which rely on smartphone‐based inertial data sequences. However, the SMC method has intrinsic flaws, such as sample impoverishment and particle degeneracy. A novel SMC approach is presented, which is built on the weighted differential evolution (WDE) algorithm. Sequential Monte Carlo approaches start with random particle placements and arrives at the desired distribution with a slower variance reduction, like in a high‐dimensional space, such as a multistory structure. Weighted differential evolution is included before the resampling procedure to guarantee the appropriate variety of the particle set, prevent the usage of an inadequate number of valid samples, and preserve smartphone user position accuracy. The values of the smartphone‐based sensors and BLE‐beacons are set as input to the SMC, which aids in fast approximating the posterior distributions, to speed up the particle congregation process in the proposed SMC‐based WDE approach. Lastly, the robustness and efficacy of the suggested technique more accurately reflect the actual situation of smartphone users. According to simulation findings, the suggested approach provides improved location estimation with reduced localization error and quick convergence. The results confirm that the proposed optimal fusion‐based SMC‐WDE scheme performs 9.92% better in terms of MAPE, 15.24% for the case of MAE, and 0.031% when evaluating based on the R2 Score.

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A Monte Carlo Algorithm for Multi-Robot Localization

Cited by 15 publications

References 55 publications

Cooperative Localization in Wireless Networks

Cooperative Localization in Wireless Networks

Map representations for mobile robot localization

Optimal fusion‐based localization method for tracking of smartphone user in tall complex buildings

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