A reconfigurable computing platform for plume tracking with mobile sensor networks

Kim, Byung Hwa; D'Souza, Colin; Voyles, Richard M.; Hesch, Joel A.; Roumeliotis, Stergios I.

doi:10.1117/12.668961

Cited by 6 publications

(6 citation statements)

References 18 publications

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“…By investigating treads in various configurations as well as a novel water hammer actuator pioneered by Perrin, et al [7], these motive modules provide a "toolbox" of sorts [10], supporting our approach to hardware/software reconfigurability [8] [9].…”

Section: Introductionmentioning

confidence: 92%

Side-Slipping Locomotion of a Miniature, Reconfigurable Limb/Tread Hybrid Robot

Voyles

Godzdanker

2008

2008 IEEE International Workshop on Safety, Security and Rescue Robotics

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Abstract-Holonomic behavior is desirable in the tight confines of a rubbled, collapsed-structure environment. But arbitrary motion is difficult to achieve, mechanically, particularly since treads are the most common form of locomotive device in search and rescue robots. We are developing a reconfigurable suite of locomotive modules that permit side-slipping locomotion. Initially designed as add-on modules to the TerminatorBot limbed crawler to create limb/tread hybrid robots, the modules can also be assembled with one another to produce holonomic differential drive robots, as well. This paper describes the design of a transverse tread module with unique buckling grousers that creates a tread/limb hybrid robot capable of both forward locomotion and transverse locomotion. Also described is a two-dimensional tread module that provides motive force in both the longitudinal and transverse directions. Two of these modules together in a differential drive configuration provides true holonomic capability. The addition of articulated linkages between modules provides holonomic serpentine behavior.

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Section: Introductionmentioning

confidence: 92%

Side-Slipping Locomotion of a Miniature, Reconfigurable Limb/Tread Hybrid Robot

Voyles

Godzdanker

2008

2008 IEEE International Workshop on Safety, Security and Rescue Robotics

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“…Finally, multi-sensor collaborative applications will have to be developed by leveraging the underlying localization, navigation, networking and sensing services. Each of these four areas has seen recent research activities [4][5][6][7][8][9][10][11] and progress towards application-driven system integration. This paper contributes towards these integration trends by developing a system that comprises all four subsystems as well as their functional integration in the context of a collaborative multi-target tracking application in indoor settings.…”

Section: Introductionmentioning

confidence: 99%

A networked mobile sensor test-bed for collaborative multi-target tracking applications

et al. 2009

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This paper presents the design, architecture, implementation, and experimental results from a networked mobile sensor test-bed developed for collaborative sensor tracking applications. The test-bed comprises a fleet of networked mobile sensors, an indoor localization system, a control, debugging and management infrastructure, and a tiered wireless ad hoc network for seamless integration of the above three components and the existing wireless infrastructure. First, the software and hardware architectural details of a swarm capable autonomous vehicle (SCAV) system for our collaborative applications are presented. Second, the details of an indoor self-localization and Kalman filter based navigation system design for the SCAV platform are presented. Third, as an example multi-sensor application, a collaborative multi-target tracking problem and a heuristics-based networked solution are formulated. Finally, the performance of the collaborative tracking framework is evaluated on the laboratory testbed for characterizing the impacts of localization and navigation errors on the distributed tracking performance. The experimental study also characterizes the tradeoff between the tracking performance and the consumed wireless bandwidth. The experimental results demonstrate a number of counterintuitive results due to various errors in sensor localization and navigation.

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“…The system is designed around an FPGA fabric that allows the user the flexibility of using different devices without having to be concerned with the interfacing details. It is based on the novel "morphing bus" concept [10]. The novelty of this architecture is the absence of interface logic on the side of the sensors and actuators with all the interface logic being moved into the FPGA.…”

Section: Introduction M Bumentioning

confidence: 99%

Morphing Bus: A rapid deployment computing architecture for high performance, resource-constrained robots

D'Souza¹,

Kim²,

Voyles

2007

Proceedings 2007 IEEE International Conference on Robotics and Automation

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Abstract-For certain applications, field robotic systems require small size for cost, weight, access, stealth or other reasons. Small size results in constraints on critical resources such as power, space (for sensors and actuators), and computing cycles, but these robots still must perform many of the challenging tasks of their larger brethren. The need for advanced capabilities such as machine vision, applicationspecific sensing, path planning, self localization, etc. is not reduced by small-scale applications, but needs may vary with the task. As a result, when resources are constrained, it is prudent to configure the robot for the task at hand; both hardware and software. We are developing a reconfigurable computing subsystem for resource-constrained robots that allows rapid deployment of statically configured hardware and software for a specific task. The use of a Field Programmable Gate Array (FPGA) provides flexibility in hardware for both sensor interfacing and hardware-accelerated computation. In this paper, we describe a static reconfiguration architecture we call the Morphing Bus that allows the rapid assembly of sensors and dedicated computation through reusable hardware and software modules. It is a novel sensor bus in the fact that no bus interface circuitry is required on the sensor side -the bus "morphs" to accommodate the signals of the sensor.

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A reconfigurable computing platform for plume tracking with mobile sensor networks

Cited by 6 publications

References 18 publications

Side-Slipping Locomotion of a Miniature, Reconfigurable Limb/Tread Hybrid Robot

Side-Slipping Locomotion of a Miniature, Reconfigurable Limb/Tread Hybrid Robot

A networked mobile sensor test-bed for collaborative multi-target tracking applications

Morphing Bus: A rapid deployment computing architecture for high performance, resource-constrained robots

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