Your search keyword '"Continuous planning"' showing total 9 results

1. Continuous planning for inertial-aided systems

Author

Usayiwevu, Mitchell, Sukkar, Fouad, Yoo, Chanyeol, Fitch, Robert, and Vidal-Calleja, Teresa

Published

2024

2. Interleaving Planning and Robot Execution for Asynchronous User Requests

Author

Haigh, Karen Zita and Veloso, Manuela M.

Published

1998

3. Punctual versus continuous auction coordination for multi-robot and multi-task topological navigation.

Author

Lozenguez, Guillaume, Adouane, Lounis, Beynier, Aurélie, Mouaddib, Abdel-Illah, and Martinet, Philippe

Subjects

DECISION making, ROBOT control systems, AUCTION theory, MARKOV processes

Abstract

This paper addresses the interest of using punctual versus continuous coordination for mobile multi-robot systems where robots use auction sales to allocate tasks between them and to compute their policies in a distributed way. In continuous coordination, one task at a time is assigned and performed per robot. In punctual coordination, all the tasks are distributed in Rendezvous phases during the mission execution. However, tasks allocation problem grows exponentially with the number of tasks. The proposed approach consists in two aspects: (1) a control architecture based on topological representation of the environment which reduces the planning complexity and (2) a protocol based on sequential simultaneous auctions (SSA) to coordinate Robots' policies. The policies are individually computed using Markov Decision Processes oriented by several goal-task positions to reach. Experimental results on both real robots and simulation describe an evaluation of the proposed robot architecture coupled wih the SSA protocol. The efficiency of missions' execution is empirically evaluated regarding continuous planning. [ABSTRACT FROM AUTHOR]

Published

2016

4. Multi-robot geometric task-and-motion planning for collaborative manipulation tasks.

Author

Zhang, Hejia, Chan, Shao-Hung, Zhong, Jie, Li, Jiaoyang, Kolapo, Peter, Koenig, Sven, Agioutantis, Zach, Schafrik, Steven, and Nikolaidis, Stefanos

Abstract

We address multi-robot geometric task-and-motion planning (MR-GTAMP) problems in synchronous, monotone setups. The goal of the MR-GTAMP problem is to move objects with multiple robots to goal regions in the presence of other movable objects. We focus on collaborative manipulation tasks where the robots have to adopt intelligent collaboration strategies to be successful and effective, i.e., decide which robot should move which objects to which positions, and perform collaborative actions, such as handovers. To endow robots with these collaboration capabilities, we propose to first collect occlusion and reachability information for each robot by calling motion-planning algorithms. We then propose a method that uses the collected information to build a graph structure which captures the precedence of the manipulations of different objects and supports the implementation of a mixed-integer program to guide the search for highly effective collaborative task-and-motion plans. The search process for collaborative task-and-motion plans is based on a Monte-Carlo Tree Search (MCTS) exploration strategy to achieve exploration-exploitation balance. We evaluate our framework in two challenging MR-GTAMP domains and show that it outperforms two state-of-the-art baselines with respect to the planning time, the resulting plan length and the number of objects moved. We also show that our framework can be applied to underground mining operations where a robotic arm needs to coordinate with an autonomous roof bolter. We demonstrate plan execution in two roof-bolting scenarios both in simulation and on robots. [ABSTRACT FROM AUTHOR]

Published

2023

5. Motion planning for robot audition.

Author

Nguyen, Quan V., Colas, Francis, Vincent, Emmanuel, and Charpillet, François

Subjects

MONTE Carlo method, ROBOT motion, ACOUSTIC localization, MICROPHONE arrays, PLANNING techniques, AUDITIONS, FALSE discovery rate, KALMAN filtering

Abstract

Robot audition refers to a range of hearing capabilities which help robots explore and understand their environment. Among them, sound source localization is the problem of estimating the location of a sound source given measurements of its angle of arrival with respect to a microphone array mounted on the robot. In addition, robot motion can help quickly solve the front-back ambiguity existing in a linear microphone array. In this article, we focus on the problem of exploiting robot motion to improve the estimation of the location of an intermittent and possibly moving source in a noisy and reverberant environment. We first propose a robust extended mixture Kalman filtering framework for jointly estimating the source location and its activity over time. Building on this framework, we then propose a long-term robot motion planning algorithm based on Monte Carlo tree search to find an optimal robot trajectory according to two alternative criteria: the Shannon entropy or the standard deviation of the estimated belief on the source location. These criteria are integrated over time using a discount factor. Experimental results show the robustness of the proposed estimation framework to false angle of arrival measurements within ± 20 ∘ and 10% false source activity detection rate. The proposed robot motion planning technique achieves an average localization error 48.7% smaller than a one-step-ahead method. In addition, we compare the correlation between the estimation error and the two criteria, and investigate the effect of the discount factor on the performance of the proposed motion planning algorithm. [ABSTRACT FROM AUTHOR]

Published

2019

6. Multi-modal active perception for information gathering in science missions.

Author

Arora, Akash, Furlong, P. Michael, Fitch, Robert, Sukkarieh, Salah, and Fong, Terrence

Subjects

MONTE Carlo method, SCIENTIFIC knowledge, INFORMATION science, LINEAR network coding, SENSORY perception, DECISION making, SPACE robotics

Abstract

Robotic science missions in remote environments, such as deep ocean and outer space, can involve studying phenomena that cannot directly be observed using on-board sensors but must be deduced by combining measurements of correlated variables with domain knowledge. Traditionally, in such missions, robots passively gather data along prescribed paths, while inference, path planning, and other high level decision making is largely performed by a supervisory science team located at a different location, often at a great distance. However, communication constraints hinder these processes, and hence the rate of scientific progress. This paper presents an active perception approach that aims to reduce robots' reliance on human supervision and improve science productivity by encoding scientists' domain knowledge and decision making process on-board. We present a Bayesian network architecture to compactly model critical aspects of scientific knowledge while remaining robust to observation and modeling uncertainty. We then formulate path planning and sensor scheduling as an information gain maximization problem, and propose a sampling-based solution based on Monte Carlo tree search to plan informative sensing actions which exploit the knowledge encoded in the network. The computational complexity of our framework does not grow with the number of observations taken and allows long horizon planning in an anytime manner, making it highly applicable to field robotics with constrained computing. Simulation results show statistically significant performance improvements over baseline methods, and we validate the practicality of our approach through both hardware experiments and simulated experiments with field data gathered during the NASA Mojave Volatiles Prospector science expedition. [ABSTRACT FROM AUTHOR]

Published

2019

7. Distributed configuration formation with modular robots using (sub)graph isomorphism-based approach.

Author

Dutta, Ayan, Dasgupta, Prithviraj, and Nelson, Carl

Subjects

ISOMORPHISM (Mathematics), ROBOTS, SCHEDULING

Abstract

We consider the problem of configuration formation in modular robot systems where a set of modules that are initially in different configurations and located at different locations are required to assume appropriate positions so that they can get into a new, user-specified, target configuration. We propose a novel algorithm based on (sub)graph isomorphism, where the modules select locations or spots in the target configuration using a utility-based framework, while retaining their original configuration to the greatest extent possible, to reduce the time and energy required by the modules to disconnect and connect multiple times to form the target configuration. We have shown analytically that our proposed algorithm is complete and guarantees a Pareto-optimal allocation. Experimental simulations of our algorithm with different numbers of modules in different initial configurations and located initially at different locations, show that the planning time of our algorithm is nominal (order of msec for 100 modules). We have also compared our algorithm against a market-based allocation algorithm and shown that our proposed algorithm performs better in terms of time and number of messages exchanged. [ABSTRACT FROM AUTHOR]

Published

2019

8. AMPLE: an anytime planning and execution framework for dynamic and uncertain problems in robotics.

Author

Ponzoni Carvalho Chanel, Caroline, Albore, Alexandre, T'Hooft, Jorrit, Lesire, Charles, and Teichteil-Königsbuch, Florent

Subjects

AUTONOMOUS robots, AUTOMATED planning & scheduling, FLEXIBILITY (Mechanics), EMBEDDED computer systems, CONCURRENT engineering

Abstract

Acting in robotics is driven by reactive and deliberative reasonings which take place in the competition between execution and planning processes. Properly balancing reactivity and deliberation is still an open question for harmonious execution of deliberative plans in complex robotic applications. We propose a flexible algorithmic framework to allow continuous real-time planning of complex tasks in parallel of their executions. Our framework, named AMPLE, is oriented towards robotic modular architectures in the sense that it turns planning algorithms into services that must be generic, reactive, and valuable. Services are optimized actions that are delivered at precise time points following requests from other modules that include states and dates at which actions are needed. To this end, our framework is divided in two concurrent processes: a planning thread which receives planning requests and delegates action selection to embedded planning softwares in compliance with the queue of internal requests, and an execution thread which orchestrates these planning requests as well as action execution and state monitoring. We show how the behavior of the execution thread can be parametrized to achieve various strategies which can differ, for instance, depending on the distribution of internal planning requests over possible future execution states in anticipation of the uncertain evolution of the system, or over different underlying planners to take several levels into account. We demonstrate the flexibility and the relevance of our framework on various robotic benchmarks and real experiments that involve complex planning problems of different natures which could not be properly tackled by existing dedicated planning approaches which rely on the standard plan-then-execute loop. [ABSTRACT FROM AUTHOR]

Published

2019

9. Online decentralized information gathering with spatial-temporal constraints.

Author

Gan, Seng, Fitch, Robert, and Sukkarieh, Salah

Subjects

INFORMATION sharing, ACQUISITION of data, ONLINE education, IMPACT (Mechanics), COMPUTER networks

Abstract

We are interested in coordinating a team of autonomous mobile sensor agents in performing a cooperative information gathering task while satisfying mission-critical spatial-temporal constraints. In particular, we present a novel set of constraint formulations that address inter-agent collisions, collisions with static obstacles, network connectivity maintenance, and temporal-coverage in a resource-efficient manner. These constraints are considered in the context of the target search problem, where the team plans trajectories that maximize the probability of target detection. We model constraints continuously along the agents' trajectories and integrate these constraint models into decentralized team planning using a computationally efficient solution method based on the Lagrangian formulation and decentralized optimization. We validate our approach in simulation with five UAVs performing search, and through hardware experiments with four indoor mobile robots. Our results demonstrate team planning with spatial-temporal constraints that preserves the performance of unconstrained information gathering and is feasible to implement with reasonable computational and communication resources. [ABSTRACT FROM AUTHOR]

Published

2014