On the Redundancy Detection in Keyframe-Based SLAM

Schmuck, Patrik; Chli, Margarita

doi:10.1109/3dv.2019.00071

Cited by 10 publications

(13 citation statements)

References 34 publications

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“…While these approaches are demonstrated to achieve accurate co-localization, they are designed for a manageable number of agents, and will not achieve real-time performance when applied to several tens or hundreds of agents. Some recent works [12], [13] have investigated how SLAM graphs can be reduced in order to boost the scalability of collaborative SLAM, demonstrating significant reductions in the data necessary to represent an environment, yet still not allowing collaborative SLAM algorithms to scale up to swarm size. Another popular approach to simplify relative localization among UAVs is to attach a salient, pre-known and unique pattern (termed marker) on each agent.…”

Section: Related Workmentioning

confidence: 99%

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Distributed Formation Estimation Via Pairwise Distance Measurements

Ziegler

Karrer

Schmuck

et al. 2021

IEEE Robot. Autom. Lett.

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Continuously and reliably estimating the relative configuration of robotic swarms in real-time constitutes a core functionality when pursuing the autonomy of such a swarm. Relying on external positioning systems, such as GPS or motion tracking systems, can provide the required information, but significantly limits the generality of an approach. In this letter, we target formation estimation for autonomous flights of swarms of small UAVs, as they pose particularly challenging restrictions on onboard resources, while opening up a large variety of practical scenarios for a multi-robot setup. While state of the art has been addressing efficient formation estimation, scalability remains limited to only very few agents that can be handled in real-time, with the workload of each agent depending on the total number of agents in the swarm. Aiming for scalable multi-robot systems, here we propose a distributed formation estimation approach, where the computational load of each agent is decoupled from the swarm size. This approach is implemented in a setup with minimal communication effort, requiring only ego-motion estimates from each agent and pairwise distance measurements between them, constraining their configuration globally. Evaluations on swarms of up to 49 UAVs demonstrate the power of our approach to handle large swarms, while keeping the computational load bounded for individual agents and requiring only little data exchange between two robots.

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Section: Related Workmentioning

confidence: 99%

“…These error terms enforce the constraints in Eq. (12). Special care has to be taken for the consensus term involving the rotation.…”

Section: Distributed Range-based Formation Estimationmentioning

confidence: 99%

Distributed Formation Estimation Via Pairwise Distance Measurements

Ziegler

Karrer

Schmuck

et al. 2021

IEEE Robot. Autom. Lett.

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“…Mutual information between two random variables. It measures how much knowing one of the variables reduces the uncertainty about the other [21]:…”

Section: Information Metricsmentioning

confidence: 99%

“…Redundancy detection using Mutual Information. As in [21], the redundancy ψ(K j ) of a keyframe with respect to the others can be expressed by…”

Section: Keyframe Marginalizationmentioning

confidence: 99%

Information-Driven Direct RGB-D Odometry

Fontan

Civera

Triebel

2020

2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)

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This paper presents an information-theoretic approach to point selection for direct RGB-D odometry. The aim is to select only the most informative measurements, in order to reduce the optimization problem with a minimal impact in the accuracy. It is usual practice in visual odometry/SLAM to track several hundreds of points, achieving real-time performance in high-end desktop PCs. Reducing their computational footprint will facilitate the implementation of odometry and SLAM in low-end platforms such as small robots and AR/VR glasses. Our experimental results show that our novel information-based selection criteria allows us to reduce the number of tracked points an order of magnitude (down to only 24 of them), achieving an accuracy similar to the state of the art (sometimes outperforming it) while reducing 10× the computational demand.

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“…At the same time, multi-agent SLAM poses significant challenges, such as accurate co-localization, ensuring consistency with multiple agents simultaneously contributing information, and managing scalability with regard to the large amount of contributed data. Several works have shown good progress tackling one ore more of these challenges over the last few years [3,11,12,18,19]. However, collaborative SLAM is a relatively young research field, albeit a very promising one.…”

Section: Introductionmentioning

confidence: 99%

COVINS: Visual-Inertial SLAM for Centralized Collaboration

Schmuck¹,

Ziegler²,

Karrer³

et al. 2021

Preprint

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Collaborative SLAM enables a group of agents to simultaneously co-localize and jointly map an environment, thus paving the way to wide-ranging applications of multi-robot perception and multi-user AR experiences by eliminating the need for external infrastructure or pre-built maps. This article presents COVINS, a novel collaborative SLAM system, that enables multi-agent, scalable SLAM in large environments and for large teams of more than 10 agents. The paradigm here is that each agent runs visual-inertial odomety independently onboard in order to ensure its autonomy, while sharing map information with the COVINS server back-end running on a powerful local PC or a remote cloud server. The server backend establishes an accurate collaborative global estimate from the contributed data, refining the joint estimate by means of place recognition, global optimization and removal of redundant data, in order to ensure an accurate, but also efficient SLAM process. A thorough evaluation of COVINS reveals increased accuracy of the collaborative SLAM estimates, as well as efficiency in both removing redundant information and reducing the coordination overhead, and demonstrates successful operation in a large-scale mission with 12 agents jointly performing SLAM.

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On the Redundancy Detection in Keyframe-Based SLAM

Cited by 10 publications

References 34 publications

Distributed Formation Estimation Via Pairwise Distance Measurements

Distributed Formation Estimation Via Pairwise Distance Measurements

Information-Driven Direct RGB-D Odometry

COVINS: Visual-Inertial SLAM for Centralized Collaboration

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