SLAP: Simultaneous Localization and Planning Under Uncertainty via Dynamic Replanning in Belief Space

Agha–mohammadi, Ali–akbar; Agarwal, Saurav; Kim, Sung-Kyun; Chakravorty, Suman; Amato, Nancy M.

doi:10.1109/tro.2018.2838556

Cited by 37 publications

(33 citation statements)

References 60 publications

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“…The pose belief is propagated with Eqs. (5) and (6) if the relative transformation is given in a deterministic form. In our problem, we plan rover's path on a map belief and the uncertainty accumulation only given as a stochastic form.…”

Section: Pose Hyper-belief Propagationmentioning

confidence: 99%

Where to Map? Iterative Rover-Copter Path Planning for Mars Exploration

Sasaki

Otsu

Thakker

et al. 2020

IEEE Robot. Autom. Lett.

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In addition to conventional ground rovers, the Mars 2020 mission will send a helicopter to Mars. The copter's highresolution data helps the rover to identify small hazards such as steps and pointy rocks, as well as providing rich textual information useful to predict perception performance. In this paper, we consider a three-agent system composed of a Mars rover, copter, and orbiter. The objective is to provide good localization to the rover by selecting an optimal path that minimizes the localization uncertainty accumulation during the rover's traverse. To achieve this goal, we quantify the localizability as a goodness measure associated with the map, and conduct a joint-space search over rover's path and copter's perceptual actions given prior information from the orbiter. We jointly address where to map by the copter and where to drive by the rover using the proposed iterative copter-rover path planner. We conducted numerical simulations using the map of Mars 2020 landing site to demonstrate the effectiveness of the proposed planner.

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Section: Pose Hyper-belief Propagationmentioning

confidence: 99%

Where to Map? Iterative Rover-Copter Path Planning for Mars Exploration

Sasaki

Otsu

Thakker

et al. 2020

IEEE Robot. Autom. Lett.

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“…This problem is known in the mobile robotics literature as distributed state estimation. The approach presented herein is similar to recent advancements in linear-Gaussian active sensing that operate in pose-covariance space [2], [3], except that here we propose a novel beliefspace discretization that admits exact value iteration and can be readily incorporated in a hierarchical multi-robot controller, enabling decentralized information acquisition of very large collections of hidden states by large teams of robots.…”

Section: Introductionmentioning

confidence: 99%

“…A preliminary version of this work can be found in [1] the covariance matrix. This is the approach followed, e.g., in mobile target tracking [4], [5], sparse landmark localization [1], [6], [7], and active SLAM [3], [8], [9]. Recently, [8] have shown that information-theoretic objectives may fail even to be monotonic in many active sensing tasks, removing performance guarantees for greedy control.…”

Section: Introductionmentioning

confidence: 99%

“…This is known as the "belief representation problem." This problem, in the context of information acquisition, has received a great deal of attention recently, both when the robot state is observable [2], [10]- [13] and when it is only partially observable [3], [14]- [21]. The most widely used approach is to grow a tree with a prior distribution of the hidden states at the root, sampling in this way several sequences of possible future observations to obtain the set of reachable belief states at the leaves.…”

Section: Introductionmentioning

confidence: 99%

“…Common in the vast majority of approaches discussed above is that mobile sensor planning relies on sampling-based strategies, e.g., forward search, for partially [3], [14], [15], [15]- [21] and fully observable [2], [13] robots, or belief space sampling in the policy domain [17]- [19]. Sampling-based approaches will typically run into scalability issues due to one or more of the following reasons: (i) sparsity of information in the environment, which forces longer planning horizons, (ii) high dimensional unknowns, which make observation sampling inefficient, or (iii) large teams of robots, which significantly increase the size of the action space.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Distributed Hierarchical Control for State Estimation With Robotic Sensor Networks

Freundlich

Zhang

Zavlanos

2018

IEEE Trans. Control Netw. Syst.

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This paper addresses active state estimation with a team of robotic sensors. The states to be estimated are represented by spatially distributed, uncorrelated, stationary vectors. Given a prior belief on the geographic locations of the states, we cluster the states in moderately sized groups and propose a new hierarchical Dynamic Programming (DP) framework to compute optimal sensing policies for each cluster that mitigates the computational cost of planning optimal policies in the combined belief space. Then, we develop a decentralized assignment algorithm that dynamically allocates clusters to robots based on the pre-computed optimal policies at each cluster. The integrated distributed state estimation framework is optimal at the cluster level but also scales very well to large numbers of states and robot sensors. We demonstrate efficiency of the proposed method in both simulations and real-world experiments using stereoscopic vision sensors.

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Perception‐aware autonomous mast motion planning for planetary exploration rovers

Strader

Otsu

Agha–mohammadi

2019

Journal of Field Robotics

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Highly accurate real-time localization is of fundamental importance for the safety and efficiency of planetary rovers exploring the surface of Mars. Mars rover operations rely on vision-based systems to avoid hazards as well as plan safe routes. However, vision-based systems operate on the assumption that sufficient visual texture is visible in the scene. This poses a challenge for vision-based navigation on Mars where regions lacking visual texture are prevalent. To overcome this, we make use of the ability of the rover to actively steer the visual sensor to improve fault tolerance and maximize the perception performance. This paper answers the question of where and when to look by presenting a method for predicting the sensor trajectory that maximizes the localization performance of the rover. This is accomplished by an online assessment of possible trajectories using synthetic, future camera views created from previous observations of the scene. The proposed trajectories are quantified and chosen based on the expected localization performance. In this work, we validate the proposed method in field experiments at the Jet Propulsion Laboratory (JPL) Mars Yard. Furthermore, multiple performance metrics are identified and evaluated for reducing the overall runtime of the algorithm. We show how actively steering the perception system increases the localization accuracy compared to traditional fixed-sensor configurations.

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SLAP: Simultaneous Localization and Planning Under Uncertainty via Dynamic Replanning in Belief Space

Cited by 37 publications

References 60 publications

Where to Map? Iterative Rover-Copter Path Planning for Mars Exploration

Where to Map? Iterative Rover-Copter Path Planning for Mars Exploration

Distributed Hierarchical Control for State Estimation With Robotic Sensor Networks

Perception‐aware autonomous mast motion planning for planetary exploration rovers

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