Photomorphogenesis for robot self-assembly: adaptivity, collective decision-making, and self-repair

Soorati, Mohammad Divband; Heinrich, Mary Katherine; Ghofrani, Javad; Zahadat, Payam; Hamann, Heiko

doi:10.1088/1748-3190/ab2958

Cited by 15 publications

(6 citation statements)

References 100 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Inspired by the robustness and adaptability of these systems, engineers have mimicked naturally occurring behaviors through robot collectives that are programmable and interact with their environment to enable robust reconfiguration. For example, at the macro-scale, Kilobot collectives use programmed interactions to create different formations 8 – 10 and reconfigure to manipulate objects based on global signal inputs 11 . Other macro-scale robot collectives demonstrate how environmental interactions like contact-based coupling 12 – 15 can enable collectives to change their shape 16 – 18 , function, and mode of locomotion 19 – 21 .…”

Section: Introductionmentioning

confidence: 99%

Microrobot collectives with reconfigurable morphologies, behaviors, and functions

et al. 2022

View full text Add to dashboard Cite

Mobile microrobots, which can navigate, sense, and interact with their environment, could potentially revolutionize biomedicine and environmental remediation. Many self-organizing microrobotic collectives have been developed to overcome inherent limits in actuation, sensing, and manipulation of individual microrobots; however, reconfigurable collectives with robust transitions between behaviors are rare. Such systems that perform multiple functions are advantageous to operate in complex environments. Here, we present a versatile microrobotic collective system capable of on-demand reconfiguration to adapt to and utilize their environments to perform various functions at the air–water interface. Our system exhibits diverse modes ranging from isotropic to anisotrpic behaviors and transitions between a globally driven and a novel self-propelling behavior. We show the transition between different modes in experiments and simulations, and demonstrate various functions, using the reconfigurability of our system to navigate, explore, and interact with the environment. Such versatile microrobot collectives with globally driven and self-propelled behaviors have great potential in future medical and environmental applications.

show abstract

Section: Introductionmentioning

confidence: 99%

Microrobot collectives with reconfigurable morphologies, behaviors, and functions

et al. 2022

View full text Add to dashboard Cite

show abstract

“…The four engineering examples evaluated were: 1) Self-healing vascular material 4 , 2) Self-adapting robot limb 5 , 3) Self-reconfiguring RAM (built-in self-repair) 6 , 4) Self-assembly robots 10 . The four biological examples evaluated were: 5) Self-sharpening teeth 11 , 6) Wet skin wrinkles 12 , 7) Self-sealing Latex plants 13 , and 8) Selfreconfiguration of jellyfish 14 .…”

Section: Methodsmentioning

confidence: 99%

A Complexity Framework for Self-Engineering Systems

Brooks

Roy

2020

Smart Sustain. Manuf. Syst.

View full text Add to dashboard Cite

To ensure extended useful life of systems during pandemics such as Covid-19, systems independent of traditional maintenance, repair and servicing will be required. Ambitious new designs are needed, such as self-engineering (SE) systems to automatically respond to return lost functionality and improve product resilience without human intervention. Development in SE has focused on self-healing materials, self-reconfiguring electronics and self-adapting robotics. There has been little work to evaluate SE systems holistically and develop new design tools for creating new SE systems. This paper presents a framework for evaluating the complexity of SE systems and the validation of the framework with expert interviews. There was agreement between experts and the authors for 21/24 of factors for the eight SE examples (four biological and four engineering) evaluated using the framework. Disagreements in results were caused by a lack of knowledge on the system being evaluated or misunderstanding about the system operation.

show abstract

“…The self-assembly of drones during flight (Li et al 2019a), including attaching and detaching mechanisms (Saldana, Gupta, and Kumar 2019) has also been investigated; however, only small size swarms of drone have been tested. A recent project attempted to use modular robots with light sensors to replicate the growth of plants towards light found in nature, photomorphogenesis (Divband Soorati et al 2019). The starting robot (or seeding point) is set at the beginning; robots then attach themselves to this seed or the robot closest toward the light, see Figure 11.…”

Section: Self-assemblymentioning

confidence: 99%