Environment-driven distributed evolutionary adaptation in a population of autonomous robotic agents

Bredèche, Nicolas; Montanier, Jean Marc; Liu, Wenguo; Winfield, Alan F. T.

doi:10.1080/13873954.2011.601425

Cited by 87 publications

(88 citation statements)

References 27 publications

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“…In the long run, this is still likely to be the case, but has been less of an issue than might have been expected. Some of the more complex tasks discussed in the literature have successfully employed aggregate or nearly aggregate fitness functions [2,56,59,61]. The ramifications of this are of interest and provide an additional point of support for the conjecture presented in the previous subsection of this paper: the set of benchmark tasks used in ER contain solutions that are less complex than previously supposed.…”

Section: B Fitness Functions Don't Scalementioning

confidence: 58%

“…Recently there have been additional advances in ER in terms of complexity of behavior [2,30,32,33,[59][60][61][62]. We will look at some of these in more detail in later sections of this paper.…”

Section: Background and Historymentioning

confidence: 99%

“…Currently more complex foraging tasks are a focus in ER. Examples include the sequential ball collection and deposition task summarized in the introduction [2] and a large-scale 100-robot foraging task evolved with an environmentally situated GA [61].…”

Section: Foragingmentioning

confidence: 99%

“…Some evolved autonomous agent behaviors seem to display a degree of scalable complexity [2,56,60,61], but this may partially reflect a functional overlap between synthesis and optimization (adaptation) processes at the lower end of task complexity. Here we suggest that controller configurations within a certain radius of a solution or optimum (in terms of A. L. Nelson in proc.…”

Section: Optimization Equals Synthesis But Only For Simple Tasksmentioning

confidence: 99%

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Embodied artificial life at an impasse can evolutionary robotics methods be scaled?

Nelson¹

2014

2014 IEEE Symposium on Evolving and Autonomous Learning Systems (EALS)

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Abstract-Evolutionary robotics (ER) investigates the application of artificial evolution toward the synthesis of robots capable of performing autonomous behaviors. Over the last 25 years, researchers have reported increasingly complex evolved behaviors, and have compiled a de facto set of benchmark tasks. Perhaps the best known of these is the obstacle avoidance and target homing task performed by differential drive robots. More complex tasks studied in recent ER work include augmented variants of the rodent T-maze and complex foraging tasks. But can proof-of-concept results such as these be extended to evolve complex autonomous behaviors in a general sense? In this topical analysis paper we survey relevant research and make the case that common tasks used to demonstrate the effectiveness of evolutionary robotics are not characteristic of more general cases and in fact do not fully prove the concept that artificial evolution can be used to evolve sophisticated autonomous agent behaviors. Robots capable of performing many of the tasks studied in ER have now been evolved using nearly aggregate binary success/fail fitness functions. However, arguments used to support the necessity of incremental methods for complex tasks are essentially sound. This raises the possibility that the tasks themselves allow for relatively simple solutions, or span a relatively small candidate solution set. This paper presents these arguments in detail and concludes with a discussion of current ER research.

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Section: B Fitness Functions Don't Scalementioning

confidence: 58%

Section: Background and Historymentioning

confidence: 99%

Section: Foragingmentioning

confidence: 99%

Section: Optimization Equals Synthesis But Only For Simple Tasksmentioning

confidence: 99%

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Embodied artificial life at an impasse can evolutionary robotics methods be scaled?

Nelson¹

2014

2014 IEEE Symposium on Evolving and Autonomous Learning Systems (EALS)

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“…For example, Filipic et al evolved control strategies for operating container cranes using a physical crane to determine fitness values 37 . The evolution of controllers is also possible in situ -for example, in a population of robots during, and not just before, their operational period 38,39 . Evolutionary robotics 40 is an especially challenging application area because of two additional issues that other branches of EC do not face: the very weak and noisy link between controllable design details and the target feature(s); and the great variety of conditions under which a solution should perform well.…”

Section: Applications Of Evolutionary Computationmentioning

confidence: 99%

From evolutionary computation to the evolution of things

Eiben¹,

Smith

2015

Nature

372

182

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Swarm Robotics

Garattoni

Birattari

2016

Wiley Encyclopedia of Electrical and Electronics Engineering

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Swarm robotics is an approach to coordinating a highly redundant group of robots. A robot swarm is an autonomous entity that acts in a self‐organized way: the complexity of its collective behaviors is the result of the local interactions between the individual robots. A robot swarm neither has a leader nor any other centralized entity that is responsible for its coordination. Self‐organization, high redundancy, and the lack of single points of failure promote fault tolerance, scalability, and flexibility. These are desired properties for systems deemed to successfully function in the real world. However, these properties also pose a challenging engineering problem: the behavior of the individual robot cannot be conceived individually: it must be conceived by considering the collective behavior that it produces when executed by a large number of robots. Designing the robot–robot and the robot–environment interactions that would result in the desired collective behavior is a difficult endeavor. Research toward the definition of an engineering methodology for designing, analyzing, and maintaining robot swarms is currently ongoing. In this article, we present swarm robotics from an engineering perspective: we describe works that contribute to the advancement of swarm robotics as an engineering field and to its forthcoming uptake in real‐world applications.

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Environment-driven distributed evolutionary adaptation in a population of autonomous robotic agents

Cited by 87 publications

References 27 publications

Embodied artificial life at an impasse can evolutionary robotics methods be scaled?

Embodied artificial life at an impasse can evolutionary robotics methods be scaled?

From evolutionary computation to the evolution of things

Swarm Robotics

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