Resilient Machines Through Continuous Self-Modeling

Bongard, Josh; Zykov, Victor; Lipson, Hod

doi:10.1126/science.1133687

Cited by 583 publications

(475 citation statements)

References 20 publications

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“…Bongard [9] provides an overview of this vein of evolutionary robotics research. Evolutionary robotics research encompasses evolutionary algorithms to develop straightforward tasks such as obstacle avoidance for differential drive robots [4] to Bongard et al's artificial ontogeny [10] that develops morphology and control in concert and from evolving diverse behaviours [11] to self-modelling [12]. What almost all these contributions to the field have in common is that the evolutionary process is employed to optimise robots to achieve some fixed user-defined objective at design time.…”

Section: Related Workmentioning

confidence: 99%

Combining Conflicting Environmental and Task Requirements in Evolutionary Robotics

Haasdijk

2015

2015 IEEE 9th International Conference on Self-Adaptive and Self-Organizing Systems

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Abstract-The MONEE framework endows collective adaptive robotic systems with the ability to combine environment-and task-driven selection pressures: it enables distributed online algorithms for learning behaviours that ensure both survival and accomplishment of user-defined tasks. This paper explores the trade-off between these two requirements that evolution must establish when the task is detrimental to survival. To this end, we investigate experiments with populations of 100 simulated robots in a foraging task scenario where successfully collecting resources negatively impacts an individual's remaining lifetime. We find that the population remains effective at the task of collecting pucks even when the negative impact of collecting a puck is as bad as halving the remaining lifetime. A quantitative analysis of the selection pressures reveals that the task-based selection exerts a higher pressure than the environment.

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Section: Related Workmentioning

confidence: 99%

Combining Conflicting Environmental and Task Requirements in Evolutionary Robotics

Haasdijk

2015

2015 IEEE 9th International Conference on Self-Adaptive and Self-Organizing Systems

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“…In the context of computer science and robotics [26,27], resilience means dependability when facing changes, or in other words, its ability to maintain dependability while assimilating change without dysfunction. In the case of MetaSelf [28], a key feature for dynamic resilience is the availability of dependability metadata at runtime.…”

Section: Resilience [5]mentioning

confidence: 99%

Self-healing and self-repairing technologies

Frei

McWilliam

Derrick

et al. 2013

Int J Adv Manuf Technol

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This article reviews the existing work in selfhealing and self-repairing technologies, including work in software engineering, materials, mechanics, electronics, MEMS, self-reconfigurable robotics, and others. It suggests a terminology and taxonomy for self-healing and selfrepair, and discusses the various related types of other self-* properties. The mechanisms and methods leading to selfhealing are reviewed, and common elements across disciplines are identified.

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“…One of the earliest types is gait control tables as in, for instance, [1] and [19]. A gait control table consist of rows of actuator commands with one column for each actuator, each row also has a condition for the transition to the next row.A second major avenue of research is that of neural networks (NN).…”

Section: Related Workmentioning

confidence: 99%

“…From the perspective of the multicellular robot bodies the basic robots are merely raw material whose physical properties do not change over time. 1 In [6] a conceptual framework for systems where robot morphologies and controllers can evolve in real-time and real-space is presented. This framework, dubbed the Triangle of Life, describes a life cycle that does not run from birth to death, but from conception (being conceived) to conception (conceiving one or more children) and it is repeated over and over again, thus creating consecutive generations of 'robot children'.…”

Section: Introductionmentioning

confidence: 99%

HyperNEAT Versus RL PoWER for Online Gait Learning in Modular Robots

d’Angelo

Weel²,

Eiben³

2014

Applications of Evolutionary Computation

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Abstract. This paper addresses a principal problem of in vivo evolution of modular multi-cellular robots, where robot 'babies' can be produced with arbitrary shapes and sizes. In such a system we need a generic learning mechanism that enables newborn morphologies to obtain a suitable gait quickly after 'birth'. In this study we investigate and compare the reinforcement learning method RL PoWeR with HyperNEAT. We conduct simulation experiments using robot morphologies with different size and complexity. The experiments give insights into the differences in solution quality and algorithm efficiency, suggesting that reinforcement learning is the preferred option for this online learning problem.

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Resilient Machines Through Continuous Self-Modeling

Cited by 583 publications

References 20 publications

Combining Conflicting Environmental and Task Requirements in Evolutionary Robotics

Combining Conflicting Environmental and Task Requirements in Evolutionary Robotics

Self-healing and self-repairing technologies

HyperNEAT Versus RL PoWER for Online Gait Learning in Modular Robots

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