Onboard Evolution of Understandable Swarm Behaviors

Jones, Simon; Winfield, Alan F. T.; Hauert, Sabine; Studley, Matthew

doi:10.1002/aisy.201900031

Cited by 28 publications

(27 citation statements)

References 31 publications

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“…Active-matter research should seek analogies with the problems studied in swarm robotics 21,77 , where genetic algorithms 21,22 (Box 1) and reinforcement learning 23 have been applied for some time. Recent trends in swarm-robotics research are deep reinforcement learning 78 , model-based behaviour trees evolved using genetic programming that result in humanreadable output 79 , and machine-learning methods based on generative adversarial networks 80 (Box 1 and Fig. 5b).…”

Section: Improvement Of Data Acquisition and Analysismentioning

confidence: 99%

Machine learning for active matter

et al. 2020

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Section: Improvement Of Data Acquisition and Analysismentioning

confidence: 99%

Machine learning for active matter

et al. 2020

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“…For these reasons, it is not surprising that, to the best of our knowledge and as confirmed by Chung et al (2018), most real-world implementations of MAV swarms to date have relied on primarily manually designed swarming algorithms. These advantages have also been acknowledged by the automatic design community, which has brought a general interest in using automatic approach to develop explicit controllers, such as state machines (Francesca et al, 2014(Francesca et al, , 2015 or behavior trees (Kuckling et al, 2018;Jones et al, 2019). In future work, the use of these methods could lead to a compromise between extracting an understandable controller and exploiting the power of automatic methods.…”

Section: Manual Vs Automatic Methods For Mav Swarmsmentioning

confidence: 99%

“…Moreover, thanks to the blind optimization, not only the controller can be evolved, but also other factors, such as the communication between robots (Ampatzis et al, 2008). Likewise, ER offers a generic approach to generate swarm controllers of different types, including, but not limited to: neural networks (Trianni et al, 2003;Silva et al, 2015), grammar rules (Ferrante et al, 2013), behavior trees (Scheper et al, 2016;Jones et al, 2018Jones et al, , 2019, and state machines (Francesca et al, 2014). Although neural network architectures can be very powerful, the advantage of the latter methods is that they can be better understood by a designer, which makes it easier to cross the "reality gap" between simulation and the real world when deploying the controllers on the real robots (Jones et al, 2019).…”

Section: Evolutionary Roboticsmentioning

confidence: 99%

A Survey on Swarming With Micro Air Vehicles: Fundamental Challenges and Constraints

et al. 2020

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This work presents a review and discussion of the challenges that must be solved in order to successfully develop swarms of Micro Air Vehicles (MAVs) for real world operations. From the discussion, we extract constraints and links that relate the local level MAV capabilities to the global operations of the swarm. These should be taken into account when designing swarm behaviors in order to maximize the utility of the group. At the lowest level, each MAV should operate safely. Robustness is often hailed as a pillar of swarm robotics, and a minimum level of local reliability is needed for it to propagate to the global level. An MAV must be capable of autonomous navigation within an environment with sufficient trustworthiness before the system can be scaled up. Once the operations of the single MAV are sufficiently secured for a task, the subsequent challenge is to allow the MAVs to sense one another within a neighborhood of interest. Relative localization of neighbors is a fundamental part of self-organizing robotic systems, enabling behaviors ranging from basic relative collision avoidance to higher level coordination. This ability, at times taken for granted, also must be sufficiently reliable. Moreover, herein lies a constraint: the design choice of the relative localization sensor has a direct link to the behaviors that the swarm can (and should) perform. Vision-based systems, for instance, force MAVs to fly within the field of view of their camera. Range or communication-based solutions, alternatively, provide omni-directional relative localization, yet can be victim to unobservable conditions under certain flight behaviors, such as parallel flight, and require constant relative excitation. At the swarm level, the final outcome is thus intrinsically influenced by the on-board abilities and sensors of the individual. The real-world behavior and operations of an MAV swarm intrinsically follow in a bottom-up fashion as a result of the local level limitations in cognition, relative knowledge, communication, power, and safety. Taking these local limitations into account when designing a global swarm behavior is key in order to take full advantage of the system, enabling local limitations to become true strengths of the swarm.

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“…The resulting distributed situational awareness could result in richer information at the level of the swarm than with central situational awareness, with actions happening at the right location and time, leading to desired collective behaviors. [8] Distributed situational awareness fundamentally is more than the sum of its parts. Pooling all the information from the robots to a central control and then using this central control to direct the actions of the individual robots would invariably lead to a loss of information.…”

Section: Individual Robots Have To Be Minimalmentioning

confidence: 99%

Distributed Situational Awareness in Robot Swarms

Jones

Milner

Sooriyabandara

et al. 2020

Advanced Intelligent Systems

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Situational awareness is a model for the process by which an operator accepts sensory inputs and knowledge and uses these to synthesize an integrated model of the environment within which they must make decisions and act. The field has expanded to many areas where humans must make decisions to control complex and dynamic systems. The controlling human must not just understand the readings of individual sensors but infer a broader systemic meaning from them within a goal framework to make valid decisions. Endsley divides this process into "perception" of the environment, "comprehension" of the situation in relation to goals, and "projection" into the future. [1] This article proposes a different concept, distributed situational awareness, which allows a swarm of robots to rapidly and accurately capture the state of an environment and act accordingly, without the need for any heavy infrastructure, central data storage and processing, or control. This is done by having every robot generate its own local situational awareness, which drives its immediate actions. The focus on local information allows robots to rely on limited-range sensing and communication capabilities such as cameras, distance sensors, or Bluetooth, which are widely available at a low cost. This richness of local information combines implicitly to form an emergent overall situational awareness, which drives the behavior of the swarm. Swarms with distributed situational awareness have the potential to be useable out of the box, in a scalable manner, across many applications, including environmental monitoring, construction, agriculture, and logistics. [2] Distributed situational awareness builds on important pieces of work in swarm robotics, especially on the use of local perception and action to drive the emergent functionality of the swarm. [3,4] Designing these local rules toward desired swarm behaviors is the central challenge of swarm engineering, with solutions found in bioinspiration or automatic discovery using artificial evolution and machine learning. [5] Focus now is on the transition from swarms in the lab to real-world applications. [2] Yet the use of swarm terminology has resulted in unnecessary barriers to their mainstream adoption, mostly due to the perception that individual robots in swarms are too simple or minimal to be used outside the laboratory and that real-world applications require easy access to centralized information about the state of the system to be useful, reliable, and easy to

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Onboard Evolution of Understandable Swarm Behaviors

Cited by 28 publications

References 31 publications

Machine learning for active matter

Machine learning for active matter

A Survey on Swarming With Micro Air Vehicles: Fundamental Challenges and Constraints

Distributed Situational Awareness in Robot Swarms

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