6 research outputs found
An auction-based approach with closed-loop bid adjustment to dynamic task allocation in robot teams
Dynamic task allocation is among the most difficult issues in multi-robot coordination, although it is imperative for a multitude of applications. Auction-based approaches are popular methods that allocate tasks to robots by assembling team information at a single location to make practicable decisions. However, a main deficiency of auction-based methods is that robots generally do not have sufficient information to estimate reliable bids to perform tasks, particularly in dynamic environments. While some techniques have been developed to improve bidding, they are mostly open-looped without feed-back adjustments to tune the bid prices for subsequent tasks of the same type. Robots' bids, if not assessed and adjusted accordingly, may not be trustworthy and would indeed impede team performance. To address this issue, we propose a closed-loop bid adjustment mechanism for auction-based multi-robot task allocation, with an aim to evaluate and improve robots' bids, and hence enhance the overall team performance. Each robot in a team maintains and uses its own track record as closed-loop feedback information to adjust and improve its bid prices. After a robot has completed a task, it assesses and records its performance to reflect the discrepancy between the bid price and the actual cost of the task. Such performance records, with time-discounting factors, are taken into account to damp out fluctuations of bid prices. Adopting this adjustment mechanism, a task would be more likely allocated to a competent robot that submits a more accurate bid price, and hence improve the overall team performance. Simulation of task allocation of free-range automated guided vehicles serving at a container terminal is presented to demonstrate the effectiveness of the adjustment mechanism.postprintThe World Congress on Engineering (WCE 2011), London, U.K., 6-8 July 2011. In Proceedings of WCE, 2011, v. 2, p. 1061-106
Improving Cost Estimation in Market-Based Coordination of a Distributed Sensing Task
While market-based approaches, such as TraderBots,
have shown much promise for efficient coordination of
multirobot teams, the cost estimation mechanism and its
impact on solution efficiency has not been investigated. This
paper provides a first analysis of the cost estimation process in
the TraderBots approach applied to a distributed sensing task.
In the presented implementation, path costs are estimated
using the D* path-planning algorithm with optimistic costing of
unknown map-cells. The reported results show increased team
efficiency when cost estimates reflect different environmental
and mission characteristics. Thus, this paper demonstrates
that market-based approaches can improve team efficiency if
cost estimates take into account environmental and mission
characteristics. These findings encourage future research on
applying learning techniques for on-line modification of cost
estimation and in market-based coordination
Improving Cost Estimation in Market-Based Coordination of a Distributed Sensing Task
Abstract β While market-based approaches, such as TraderBots, have shown much promise for efficient coordination of multirobot teams, the cost estimation mechanism and its impact on solution efficiency has not been investigated. This paper provides a first analysis of the cost estimation process in the TraderBots approach applied to a distributed sensing task. In the presented implementation, path costs are estimated using the D * path-planning algorithm with optimistic costing of unknown map-cells. The reported results show increased team efficiency when cost estimates reflect different environmental and mission characteristics. Thus, this paper demonstrates that market-based approaches can improve team efficiency if cost estimates take into account environmental and mission characteristics. These findings encourage future research on applying learning techniques for on-line modification of cost estimation and in market-based coordination