Social Integrating Robots Suggest Mitigation Strategies for Ecosystem Decay

Schmickl, Thomas; Szopek, Martina; Mondada, Francesco; Mills, Rob; Stefanec, Martin; Hofstadler, Daniel Nicolas; Lazic, Dajana; Barmak, Rafael; Bonnet, Frank; Zahadat, Payam

doi:10.3389/fbioe.2021.612605

Cited by 12 publications

(12 citation statements)

References 104 publications

(145 reference statements)

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“…There is also an application aspect to be considered here: Understanding the complex adaptive system at the core of honeybee colonies can help in designing novel smart beehives, in which technological devices are capable of producing exactly these physical stimuli and may thus exert a regulatory support for colonies in distress, e.g., by motivating them to keep up brood production in adverse environments or colony situations. We see this as a potential cornerstone in developing modern "smart beehives" that go beyond mere sensing by actively promoting the stability and robustness of the colony [34,35].…”

Section: Discussionmentioning

confidence: 99%

Simple Physical Interactions Yield Social Self-Organization in Honeybees

et al. 2021

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Social insect colonies show all characteristics of complex adaptive systems (CAS). Their complex behavioral patterns arise from social interactions that are based on the individuals’ reactions to and interactions with environmental stimuli. We study here how social and environmental factors modulate and bias the collective thermotaxis of young honeybees. Therefore, we record their collective decision-making in a series of laboratory experiments and derived a mathematical model of the collective decision-making in young bees from our empirical observations. This model uses only one free parameter that combines the ultimate effects of several aspects of the microscopic individual behavioral mechanisms, such as motion behavior, sensory range, or contact detection, into one single coefficient. We call this coefficient the “social factor.” Our model is capable of capturing the observed aggregation patterns from our empiric experiments with static environments and of predicting the emergent swarm-intelligent behavior of the system in dynamic environments. Besides the fundamental research aspect in studying CAS, our model enables us to predict the effects of a physical stimulus onto the macroscopic collective decision-making that affects several crucial prerequisites for efficient and effective brood production and population growth in honeybee colonies.

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Section: Discussionmentioning

confidence: 99%

Simple Physical Interactions Yield Social Self-Organization in Honeybees

et al. 2021

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“…The approach to incorporate supportive technology into social insect colonies, or into other animal societies, is called “Organismic Augmentation” ( Schmickl et al, 2021 ; Ilgün et al, 2021 ). The research project RoboRoyale works towards augmenting superorganisms with supportive technology in a novel way, by concentrating on the honeybee queen.…”

Section: Discussionmentioning

confidence: 99%

“…How the technological augmentation of superorganisms, for example, honeybee colonies, can be achieved to create novel biohybrid entities has been demonstrated in various research projects in the past ( Schmickl et al, 2021 ). Figures 10E–G depict which methods are applied most often:…”

Section: Discussionmentioning

confidence: 99%

“…In some sense, this experiment hinted how ecological linkages could be artificially created and showed that it is possible for two groups of organisms very distant from each other (spatially, developmentally, temporally, and on a size scale) to jointly make self-organized collective decisions, a process that can be interpreted as the first artificially created ecological interaction ( Bonnet et al, 2019 ). We call this paradigm of ecosystem stabilization “Ecosystem Hacking” (EH) ( Ilgün et al, 2021 ; Schmickl et al, 2021 ). The social integration of robots into animal societies is a form of “Organismic Augmentation” (OA), as it augments an existing animal superorganism with new capabilities, e.g.…”

Section: Introductionmentioning

confidence: 99%

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A Minimally Invasive Approach Towards “Ecosystem Hacking” With Honeybees

et al. 2022

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Honey bees live in colonies of thousands of individuals, that not only need to collaborate with each other but also to interact intensively with their ecosystem. A small group of robots operating in a honey bee colony and interacting with the queen bee, a central colony element, has the potential to change the collective behavior of the entire colony and thus also improve its interaction with the surrounding ecosystem. Such a system can be used to study and understand many elements of bee behavior within hives that have not been adequately researched. We discuss here the applicability of this technology for ecosystem protection: A novel paradigm of a minimally invasive form of conservation through “Ecosystem Hacking”. We discuss the necessary requirements for such technology and show experimental data on the dynamics of the natural queen’s court, initial designs of biomimetic robotic surrogates of court bees, and a multi-agent model of the queen bee court system. Our model is intended to serve as an AI-enhanceable coordination software for future robotic court bee surrogates and as a hardware controller for generating nature-like behavior patterns for such a robotic ensemble. It is the first step towards a team of robots working in a bio-compatible way to study honey bees and to increase their pollination performance, thus achieving a stabilizing effect at the ecosystem level.

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“…Similarly, passive acoustic networks are available at basin scales to track phenology and distribution for mobile protected species (Davis et al 2020 ), allowing improved inference about the seasonal overlap between populations and conventional surveys. Biohybrid systems (e.g., ‘FishBots’ that can mimic biological counterparts) also show promise for enabling in situ data collection (Schmickl et al 2021 ). Future autonomous sampling research should focus on the evolution of joint survey platforms that combine multiple collection methods without substantially increasing vessel days or labor requirements (e.g., simultaneous collection of acoustic, video, oceanographic, and environmental DNA, eDNA, data).…”

Section: Novel Data To Stimulate Improvements In Scientific Advicementioning

confidence: 99%

Oceans of plenty? Challenges, advancements, and future directions for the provision of evidence-based fisheries management advice

Goethel

Omori

Punt

et al. 2022

Rev Fish Biol Fisheries

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Marine population modeling, which underpins the scientific advice to support fisheries interventions, is an active research field with recent advancements to address modern challenges (e.g., climate change) and enduring issues (e.g., data limitations). Based on discussions during the ‘Land of Plenty’ session at the 2021 World Fisheries Congress, we synthesize current challenges, recent advances, and interdisciplinary developments in biological fisheries models (i.e., data-limited, stock assessment, spatial, ecosystem, and climate), management strategy evaluation, and the scientific advice that bridges the science-policy interface. Our review demonstrates that proliferation of interdisciplinary research teams and enhanced data collection protocols have enabled increased integration of spatiotemporal, ecosystem, and socioeconomic dimensions in many fisheries models. However, not all management systems have the resources to implement model-based advice, while protocols for sharing confidential data are lacking and impeding research advances. We recommend that management and modeling frameworks continue to adopt participatory co-management approaches that emphasize wider inclusion of local knowledge and stakeholder input to fill knowledge gaps and promote information sharing. Moreover, fisheries management, by which we mean the end-to-end process of data collection, scientific analysis, and implementation of evidence-informed management actions, must integrate improved communication, engagement, and capacity building, while incorporating feedback loops at each stage. Increasing application of management strategy evaluation is viewed as a critical unifying component, which will bridge fisheries modeling disciplines, aid management decision-making, and better incorporate the array of stakeholders, thereby leading to a more proactive, pragmatic, transparent, and inclusive management framework–ensuring better informed decisions in an uncertain world. Supplementary Information The online version contains supplementary material available at 10.1007/s11160-022-09726-7.

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Social Integrating Robots Suggest Mitigation Strategies for Ecosystem Decay

Cited by 12 publications

References 104 publications

Simple Physical Interactions Yield Social Self-Organization in Honeybees

Simple Physical Interactions Yield Social Self-Organization in Honeybees

A Minimally Invasive Approach Towards “Ecosystem Hacking” With Honeybees

Oceans of plenty? Challenges, advancements, and future directions for the provision of evidence-based fisheries management advice

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