Surviving by Serving: Functional Relevance Drives Self-Organization in Complex Adaptive Systems

Achim Schilling; Ali Ghebleh; Andreas Maier; Claus Metzner; Patrick Krauss; Thomas Kinfe

arxiv: 2606.26733 · v1 · pith:MYV74VYRnew · submitted 2026-06-25 · 🧬 q-bio.NC · cs.NE· nlin.AO

Surviving by Serving: Functional Relevance Drives Self-Organization in Complex Adaptive Systems

Claus Metzner , Ali Ghebleh , Achim Schilling , Andreas Maier , Thomas Kinfe , Patrick Krauss This is my paper

Pith reviewed 2026-06-26 02:23 UTC · model grok-4.3

classification 🧬 q-bio.NC cs.NEnlin.AO

keywords self-organizationcomplex adaptive systemsmulti-agent modelfunctional utilizationinteraction networkscore-periphery organizationpre-adaptive searchtransformation chains

0 comments

The pith

Functional utilization feedback drives spontaneous self-organization into stable networks in multi-agent systems.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper proposes Surviving by Serving as a principle in which components of a complex adaptive system persist when their outputs are utilized by others and adapt or explore when unused. A minimal multi-agent model implements this via local feedback alone, with agents transforming shared resources and receiving signals only on subsequent utilization. The model produces transformation chains, core-periphery structures, and novel states that reach new conditions, all without global objectives or external selection. This matters because it identifies a local, substrate-independent route by which organized function can emerge and stabilize from initially unstructured interactions.

Core claim

The authors argue that local functional utilization feedback is sufficient for components to self-organize into persistent interaction networks, including stable transformation chains and core-periphery architecture, while also generating novel states that enable previously unreachable conditions; these networks arise even in the absence of external selection pressures, thereby creating a pre-adaptive search phase from which functional solutions can later emerge.

What carries the argument

The minimal multi-agent model in which agents transform shared resources and receive local feedback exclusively when their outputs are subsequently utilized by other agents.

If this is right

Stable transformation chains form through repeated local utilization events.
Core-periphery organization appears spontaneously in the interaction network.
Novel states are produced that allow the system to reach target conditions inaccessible before.
Self-sustaining networks develop without any external selection pressure.
A pre-adaptive exploration phase precedes the emergence of functional solutions.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The same local rule could be tested in chemical reaction networks or economic models to check whether unused components are preferentially modified.
Adding spatial embedding or stochastic noise to the model might reveal whether chain formation remains robust under more realistic conditions.
In neural or genetic systems this mechanism could predict that rarely used connections or pathways are more likely to be rewired or lost over time.
Extensions that vary the number of agents or resource types could show the range of system sizes in which the organization persists.

Load-bearing premise

That the specific adaptation rules and resource-sharing mechanics chosen for this minimal model suffice to demonstrate the general Surviving by Serving principle rather than producing organization through model-specific artifacts.

What would settle it

Running the simulation after removing the local utilization feedback signal and checking whether transformation chains and core-periphery organization still appear or whether the agents remain in an unstructured, non-functional state.

Figures

Figures reproduced from arXiv: 2606.26733 by Achim Schilling, Ali Ghebleh, Andreas Maier, Claus Metzner, Patrick Krauss, Thomas Kinfe.

**Figure 1.** Figure 1: Main idea and adaptive interaction network. (a) Principle of “Surviving by Serving”: Components or agents (green) receive local reinforcement signals (blue) when their outputs, functions, or states (red) are utilized by other components or contribute to externally relevant outcomes. Without continued reinforcement, components remain subject to adaptation. (b) In the model, raw materials (blue squares) ar… view at source ↗

**Figure 2.** Figure 2: Emergence of a functional interaction network. (a) The probability of adaptation increases with the number of consecutive credit-less time steps according to the Hill-type rule used in the simulation. (b) Existing agents, agents credited in the previous episode, and agents adapted in the previous episode over time. (c) Number of generated states and unique state types present in the interaction space. (d) … view at source ↗

**Figure 3.** Figure 3: Overcoming the Missing Dimension Hurdle. (a) Number of generated states and unique state types present in the interaction space for the component-0-constrained diagnostic run. (b) Cumulative state selections by the two evaluators. (c) State vectors in the interaction space projected onto components 0 and 1 at selected times up to the first full-target episode. Raw materials start with zero component-0 ampl… view at source ↗

**Figure 4.** Figure 4: Formation of a Core Network (Strong Cluster Example). (a) Counts of pairwise state transfers between agents, represented by gray values, are shown in consecutive 50-episode windows. In the simulation, evaluator activity is disabled during the first 500 episodes and enabled from episode 501 onward. The title of each matrix shows the time window and the numbers of selections by the two evaluators C0 and C1 d… view at source ↗

**Figure 5.** Figure 5: Formation of a Core Network (Weaker Cluster Example). (a) Counts of pairwise state transfers between agents, represented by gray values, are shown in consecutive 50-episode windows. In the simulation, evaluator activity is disabled during the first 500 episodes and enabled from episode 501 onward. The title of each matrix shows the time window and the numbers of selections by the two evaluators C0 and C1 d… view at source ↗

**Figure 6.** Figure 6: Effect of the acceptance threshold on the adaptive network. Several key indicators of the collective dynamics are computed as a function of the acceptance threshold Θacc. Results are averaged over 50 repetitions for each value of Θacc, using the same 50 random seeds each time. Evaluator activity was enabled from the beginning of each run. From top to bottom, the panels show the fraction of runs reaching th… view at source ↗

read the original abstract

Complex adaptive systems often develop organized structures without centralized control. Yet the local mechanisms by which functional organization emerges and persists remain incompletely understood. Here we propose Surviving by Serving (SBS) as a general principle of self-organization: components persist as long as their outputs are utilized by other components, whereas prolonged non-utilization promotes adaptation and exploration. To investigate this idea, we introduce a minimal multi-agent model in which agents transform shared resources and receive only local feedback when their outputs are subsequently utilized elsewhere in the system. Despite the absence of global objectives, the system spontaneously self-organizes into functional interaction networks. We observe the emergence of stable transformation chains, core-periphery organization, and the generation of novel states that enable previously inaccessible target conditions to be reached. Remarkably, self-sustaining interaction networks can arise even without external selection pressures, creating a pre-adaptive search phase from which later functional solutions emerge. These findings suggest that functional utilization may provide a simple, substrate-independent mechanism for the emergence and stabilization of organized structure in complex adaptive systems.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The SBS principle offers a plausible local mechanism for self-organization but the minimal model needs full methods to rule out artifacts.

read the letter

The main takeaway is that this paper frames functional utilization as a driver of self-organization: agents persist when their outputs get used by others and adapt when they don't, leading to chains, core-periphery structure, and new reachable states in a shared-resource multi-agent setup with no global goal. The claim is that this can happen without external selection, creating a pre-adaptive phase.

The work does a decent job laying out a substrate-independent story and showing how local feedback alone might bootstrap organized networks. The observations about novel states enabling new targets are a concrete plus, and the model stays minimal on the surface, which fits the goal of generality.

The soft spot is exactly the one in the stress-test note. The abstract gives no equations, no parameter values, no details on how "utilized" is defined or how resources are shared, so it's impossible to tell whether the reported structures come from the proposed principle or from unstated mechanics in the adaptation rule or resource dynamics. If those details turn out to be standard and the outcomes hold across reasonable variations, the result strengthens; otherwise it stays model-specific. No math or data is shown here to check either way.

This is aimed at people working on complex adaptive systems, autopoiesis, or minimal models in biology and AI. A reader looking for simple local rules that produce global order without fitness functions could get value from the framing. It deserves a serious referee to examine the full simulations and robustness checks, even if the current version is preliminary.

Referee Report

1 major / 0 minor

Summary. The paper proposes 'Surviving by Serving' (SBS) as a general principle of self-organization in complex adaptive systems: components persist when their outputs are utilized by others, while non-utilization drives adaptation. It introduces a minimal multi-agent model in which agents transform shared resources and receive only local feedback on utilization. The abstract claims that, without global objectives or external selection, the system spontaneously forms stable transformation chains, core-periphery structures, and novel states enabling new target conditions, suggesting functional utilization as a substrate-independent mechanism.

Significance. If the minimal model rigorously demonstrates that local utilization feedback alone suffices for the reported structures in a manner independent of specific implementation details, the result would offer a simple, falsifiable mechanism for functional organization with potential relevance to biological, ecological, and artificial systems. The absence of external selection and the pre-adaptive search phase are conceptually attractive strengths. However, without equations, parameters, or quantitative results, the significance cannot yet be assessed.

major comments (1)

[Abstract / Model description] Abstract / Model section: The central claim that 'local utilization feedback alone produces self-organization (stable chains, core-periphery, novel states) in a substrate-independent manner' cannot be evaluated because the manuscript provides no equations defining agent transformation rules, resource sharing mechanics, the precise definition of 'utilized', adaptation/exploration rules, or any simulation parameters and quantitative outcomes. This is load-bearing for the general SBS principle, as the skeptic correctly notes that unstated details could generate the structures via model-specific dynamics rather than the proposed mechanism.

Simulated Author's Rebuttal

1 responses · 0 unresolved

We thank the referee for their thoughtful review and for highlighting the need for greater transparency in the model specification. We agree that the absence of explicit equations, parameters, and quantitative results in the submitted manuscript prevents full evaluation of the central claims. We will revise the manuscript accordingly.

read point-by-point responses

Referee: [Abstract / Model description] Abstract / Model section: The central claim that 'local utilization feedback alone produces self-organization (stable chains, core-periphery, novel states) in a substrate-independent manner' cannot be evaluated because the manuscript provides no equations defining agent transformation rules, resource sharing mechanics, the precise definition of 'utilized', adaptation/exploration rules, or any simulation parameters and quantitative outcomes. This is load-bearing for the general SBS principle, as the skeptic correctly notes that unstated details could generate the structures via model-specific dynamics rather than the proposed mechanism.

Authors: We fully agree that the model must be specified in sufficient detail for the claims to be evaluated. The submitted version omitted the formal description of the agent update rules, the precise definition of utilization feedback, the resource transformation function, the adaptation mechanism, and the simulation parameters. In the revision we will add a dedicated Model section containing: (i) the mathematical definition of each agent's transformation rule and the shared resource vector; (ii) the local utilization signal and its update rule; (iii) the exploration/adaptation rule (including any stochastic component); (iv) all numerical parameters and initial conditions; and (v) quantitative metrics (e.g., chain stability, core-periphery indices, novelty counts) with statistical summaries across runs. These additions will allow readers to verify that the reported structures emerge from the local feedback rule rather than from hidden implementation choices. revision: yes

Circularity Check

0 steps flagged

No circularity: model implements stated principle without reduction to fitted inputs or self-citations

full rationale

The provided text (abstract and description) introduces SBS as a conceptual principle defined by local utilization feedback and adaptation on non-utilization, then describes a minimal multi-agent model explicitly built to embody that rule. No equations, parameter-fitting procedures, self-citations, or uniqueness theorems are present that would allow any result to reduce to its inputs by construction. The observed self-organization is a direct consequence of the implemented rules rather than a tautological renaming or fitted prediction, making the derivation self-contained as a simulation demonstration.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 0 invented entities

Only the abstract is available; no specific free parameters, axioms, or invented entities can be identified from the provided text.

pith-pipeline@v0.9.1-grok · 5733 in / 1141 out tokens · 48953 ms · 2026-06-26T02:23:41.949760+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

45 extracted references

[1]

More is different: broken symmetry and the nature of the hierarchical structure of science.Science, 177(4047):393–396, 1972

Philip W Anderson. More is different: broken symmetry and the nature of the hierarchical structure of science.Science, 177(4047):393–396, 1972

1972
[2]

Complex adaptive systems.Daedalus, 121(1):17–30, 1992

John H Holland. Complex adaptive systems.Daedalus, 121(1):17–30, 1992

1992
[3]

Oxford university press, 2009

Melanie Mitchell.Complexity: A guided tour. Oxford university press, 2009

2009
[4]

Network science.Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 371(1987):20120375, 2013

Albert-L´ aszl´ o Barab´ asi. Network science.Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 371(1987):20120375, 2013

1987
[5]

Self-organization in biological systems

Scott Camazine, Jean-Louis Deneubourg, Guy Theraula, James Sneyd, and Nigel R Franks. Self-organization in biological systems. Princeton university press, 2020

2020
[6]

Springer Science & Business Media, 2012

Manfred Eigen and Peter Schuster.The hypercycle: a principle of natural self-organization. Springer Science & Business Media, 2012

2012
[7]

The origins of order: Self-organization and selection in evolution

Stuart A Kauffman. The origins of order: Self-organization and selection in evolution. InSpin glasses and biology, pages 61–100. World Scientific, 1992

1992
[8]

Autocatalytic networks at the basis of life’s origin and organiza- tion.Life, 8(4):62, 2018

Wim Hordijk and Mike Steel. Autocatalytic networks at the basis of life’s origin and organiza- tion.Life, 8(4):62, 2018

2018
[9]

Springer Science & Business Media, 2012

Humberto R Maturana and Francisco J Varela.Autopoiesis and cognition: The realization of the living. Springer Science & Business Media, 2012

2012
[10]

Biological autonomy.A philo, 14, 2015

Alvaro Moreno and Matteo Mossio. Biological autonomy.A philo, 14, 2015

2015
[11]

Biological organisation as closure of constraints.Journal of theoretical biology, 372:179–191, 2015

Ma¨ el Mont´ evil and Matteo Mossio. Biological organisation as closure of constraints.Journal of theoretical biology, 372:179–191, 2015

2015
[12]

Springer, Berlin, 1979

Manfred Eigen and Peter Schuster.The Hypercycle: A Principle of Natural Self-Organization. Springer, Berlin, 1979

1979
[13]

Kauffman.The Origins of Order: Self-Organization and Selection in Evolution

Stuart A. Kauffman.The Origins of Order: Self-Organization and Selection in Evolution. Oxford University Press, New York, 1993

1993
[14]

Detecting autocatalytic, self-sustaining sets in chemical reaction systems.Journal of Theoretical Biology, 227(4):451–461, 2004

Wim Hordijk and Mike Steel. Detecting autocatalytic, self-sustaining sets in chemical reaction systems.Journal of Theoretical Biology, 227(4):451–461, 2004

2004
[15]

The structure of autocatalytic sets: Evolvabil- ity, enablement, and emergence.Acta Biotheoretica, 60(4):379–392, 2012

Wim Hordijk, Mike Steel, and Stuart Kauffman. The structure of autocatalytic sets: Evolvabil- ity, enablement, and emergence.Acta Biotheoretica, 60(4):379–392, 2012

2012
[16]

Maturana and Francisco J

Humberto R. Maturana and Francisco J. Varela.Autopoiesis and Cognition: The Realization of the Living. D. Reidel Publishing Company, Dordrecht, 1980

1980
[17]

Varela.Principles of Biological Autonomy

Francisco J. Varela.Principles of Biological Autonomy. North-Holland, New York, 1979

1979
[18]

The computational boundary of a “self”: developmental bioelectricity drives multicellularity and scale-free cognition.Frontiers in psychology, 10:493866, 2019

Michael Levin. The computational boundary of a “self”: developmental bioelectricity drives multicellularity and scale-free cognition.Frontiers in psychology, 10:493866, 2019. 20

2019
[19]

Michael Levin. Life, death, and self: Fundamental questions of primitive cognition viewed through the lens of body plasticity and synthetic organisms.Biochemical and Biophysical Re- search Communications, 564:114–133, 2021

2021
[20]

Artificial life: organization, adaptation and complexity from the bottom up

Mark A Bedau. Artificial life: organization, adaptation and complexity from the bottom up. Trends in cognitive sciences, 7(11):505–512, 2003

2003
[21]

Adam Smith.An Inquiry into the Nature and Causes of the Wealth of Nations. W. Strahan and T. Cadell, London, 1776
[22]

Friedrich A. Hayek. The use of knowledge in society.The American Economic Review, 35(4):519– 530, 1945

1945
[23]

Borgatti and Martin G

Stephen P. Borgatti and Martin G. Everett. Models of core/periphery structures.Social Net- works, 21(4):375–395, 1999

1999
[24]

Structure and dynamics of core/periphery networks.Journal of Complex Networks, 1(2):93–123, 2013

Peter Csermely, Andras London, Ling-Yun Wu, and Brian Uzzi. Structure and dynamics of core/periphery networks.Journal of Complex Networks, 1(2):93–123, 2013

2013
[25]

Brian Arthur

W. Brian Arthur. Foundations of complexity economics.Nature Reviews Physics, 3:136–145, 2021

2021
[26]

Agent-based computational economics: Growing economies from the bottom up.Artificial Life, 8(1):55–82, 2002

Leigh Tesfatsion. Agent-based computational economics: Growing economies from the bottom up.Artificial Life, 8(1):55–82, 2002

2002
[27]

Epstein and Robert Axtell.Growing Artificial Societies: Social Science from the Bottom Up

Joshua M. Epstein and Robert Axtell.Growing Artificial Societies: Social Science from the Bottom Up. MIT Press, Cambridge, MA, 1996

1996
[28]

Stephen Jay Gould and Elisabeth S. Vrba. Exaptation–a missing term in the science of form. Paleobiology, 8(1):4–15, 1982

1982
[29]

Kauffman.Investigations

Stuart A. Kauffman.Investigations. Oxford University Press, New York, 2000

2000
[30]

Brian Arthur.The Nature of Technology: What It Is and How It Evolves

W. Brian Arthur.The Nature of Technology: What It Is and How It Evolves. Free Press, New York, 2009

2009
[31]

echo state

Herbert Jaeger. The “echo state” approach to analysing and training recurrent neural networks- with an erratum note.Bonn, Germany: German National Research Center for Information Technology GMD Technical Report, 148(34):13, 2001

2001
[32]

Real-time computing without stable states: A new framework for neural computation based on perturbations.Neural compu- tation, 14(11):2531–2560, 2002

Wolfgang Maass, Thomas Natschl¨ ager, and Henry Markram. Real-time computing without stable states: A new framework for neural computation based on perturbations.Neural compu- tation, 14(11):2531–2560, 2002

2002
[33]

Reservoir computing approaches to recurrent neural network training.Computer Science Review, 3(3):127–149, 2009

Mantas Lukoˇ seviˇ cius and Herbert Jaeger. Reservoir computing approaches to recurrent neural network training.Computer Science Review, 3(3):127–149, 2009

2009
[34]

Analysis of structure and dynamics in three-neuron motifs.Frontiers in Computational Neuroscience, 13:5, 2019

Patrick Krauss, Alexandra Zankl, Achim Schilling, Holger Schulze, and Claus Metzner. Analysis of structure and dynamics in three-neuron motifs.Frontiers in Computational Neuroscience, 13:5, 2019

2019
[35]

Recurrence resonance” in three-neuron motifs.Frontiers in computational neuroscience, 13, 2019

Patrick Krauss, Karin Prebeck, Achim Schilling, and Claus Metzner. Recurrence resonance” in three-neuron motifs.Frontiers in computational neuroscience, 13, 2019

2019
[36]

Weight statistics controls dynamics in recurrent neural networks.PloS one, 14(4):e0214541, 2019

Patrick Krauss, Marc Schuster, Verena Dietrich, Achim Schilling, Holger Schulze, and Claus Met- zner. Weight statistics controls dynamics in recurrent neural networks.PloS one, 14(4):e0214541, 2019. 21

2019
[37]

Dynamical phases and resonance phenomena in information- processing recurrent neural networks.arXiv preprint arXiv:2108.02545, 2021

Claus Metzner and Patrick Krauss. Dynamical phases and resonance phenomena in information- processing recurrent neural networks.arXiv preprint arXiv:2108.02545, 2021

arXiv 2021
[38]

Dynamics and information import in recurrent neural net- works.Frontiers in Computational Neuroscience, 16, 2022

Claus Metzner and Patrick Krauss. Dynamics and information import in recurrent neural net- works.Frontiers in Computational Neuroscience, 16, 2022

2022
[39]

Quan- tifying and maximizing the information flux in recurrent neural networks.Neural Computation, 36(3):351–384, 2024

Claus Metzner, Marius E Yamakou, Dennis Voelkl, Achim Schilling, and Patrick Krauss. Quan- tifying and maximizing the information flux in recurrent neural networks.Neural Computation, 36(3):351–384, 2024

2024
[40]

Recurrence resonance- noise-enhanced dynamics in recurrent neural networks.Frontiers in Complex Systems, 2:1479417, 2024

Claus Metzner, Achim Schilling, Andreas Maier, and Patrick Krauss. Recurrence resonance- noise-enhanced dynamics in recurrent neural networks.Frontiers in Complex Systems, 2:1479417, 2024

2024
[41]

Nonlinear neural dynamics and classification accuracy in reservoir computing.Neural Computation, 37(8):1469–1504, 2025

Claus Metzner, Achim Schilling, Andreas Maier, and Patrick Krauss. Nonlinear neural dynamics and classification accuracy in reservoir computing.Neural Computation, 37(8):1469–1504, 2025

2025
[42]

Organizational regularities in recurrent neural networks.Frontiers in Complex Systems, 3:1636222, 2025

Claus Metzner, Achim Schilling, Andreas Maier, and Patrick Krauss. Organizational regularities in recurrent neural networks.Frontiers in Complex Systems, 3:1636222, 2025

2025
[43]

Sorn: a self-organizing recurrent neural network.Frontiers in Computational Neuroscience, 3:23, 2009

Andreea Lazar, Gordon Pipa, and Jochen Triesch. Sorn: a self-organizing recurrent neural network.Frontiers in Computational Neuroscience, 3:23, 2009

2009
[44]

Rumelhart, Geoffrey E

David E. Rumelhart, Geoffrey E. Hinton, and Ronald J. Williams. Learning representations by back-propagating errors.Nature, 323(6088):533–536, 1986

1986
[45]

Surviving by Serv- ing

Yann LeCun, Yoshua Bengio, and Geoffrey Hinton. Deep learning.nature, 521(7553):436–444, 2015. 22 output input agent function/ product reward (a) (b) Figure 1:Main idea and adaptive interaction network. (a)Principle of “Surviving by Serv- ing”: Components or agents (green) receive local reinforcement signals (blue) when their outputs, functions, or states...

2015

[1] [1]

More is different: broken symmetry and the nature of the hierarchical structure of science.Science, 177(4047):393–396, 1972

Philip W Anderson. More is different: broken symmetry and the nature of the hierarchical structure of science.Science, 177(4047):393–396, 1972

1972

[2] [2]

Complex adaptive systems.Daedalus, 121(1):17–30, 1992

John H Holland. Complex adaptive systems.Daedalus, 121(1):17–30, 1992

1992

[3] [3]

Oxford university press, 2009

Melanie Mitchell.Complexity: A guided tour. Oxford university press, 2009

2009

[4] [4]

Network science.Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 371(1987):20120375, 2013

Albert-L´ aszl´ o Barab´ asi. Network science.Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 371(1987):20120375, 2013

1987

[5] [5]

Self-organization in biological systems

Scott Camazine, Jean-Louis Deneubourg, Guy Theraula, James Sneyd, and Nigel R Franks. Self-organization in biological systems. Princeton university press, 2020

2020

[6] [6]

Springer Science & Business Media, 2012

Manfred Eigen and Peter Schuster.The hypercycle: a principle of natural self-organization. Springer Science & Business Media, 2012

2012

[7] [7]

The origins of order: Self-organization and selection in evolution

Stuart A Kauffman. The origins of order: Self-organization and selection in evolution. InSpin glasses and biology, pages 61–100. World Scientific, 1992

1992

[8] [8]

Autocatalytic networks at the basis of life’s origin and organiza- tion.Life, 8(4):62, 2018

Wim Hordijk and Mike Steel. Autocatalytic networks at the basis of life’s origin and organiza- tion.Life, 8(4):62, 2018

2018

[9] [9]

Springer Science & Business Media, 2012

Humberto R Maturana and Francisco J Varela.Autopoiesis and cognition: The realization of the living. Springer Science & Business Media, 2012

2012

[10] [10]

Biological autonomy.A philo, 14, 2015

Alvaro Moreno and Matteo Mossio. Biological autonomy.A philo, 14, 2015

2015

[11] [11]

Biological organisation as closure of constraints.Journal of theoretical biology, 372:179–191, 2015

Ma¨ el Mont´ evil and Matteo Mossio. Biological organisation as closure of constraints.Journal of theoretical biology, 372:179–191, 2015

2015

[12] [12]

Springer, Berlin, 1979

Manfred Eigen and Peter Schuster.The Hypercycle: A Principle of Natural Self-Organization. Springer, Berlin, 1979

1979

[13] [13]

Kauffman.The Origins of Order: Self-Organization and Selection in Evolution

Stuart A. Kauffman.The Origins of Order: Self-Organization and Selection in Evolution. Oxford University Press, New York, 1993

1993

[14] [14]

Detecting autocatalytic, self-sustaining sets in chemical reaction systems.Journal of Theoretical Biology, 227(4):451–461, 2004

Wim Hordijk and Mike Steel. Detecting autocatalytic, self-sustaining sets in chemical reaction systems.Journal of Theoretical Biology, 227(4):451–461, 2004

2004

[15] [15]

The structure of autocatalytic sets: Evolvabil- ity, enablement, and emergence.Acta Biotheoretica, 60(4):379–392, 2012

Wim Hordijk, Mike Steel, and Stuart Kauffman. The structure of autocatalytic sets: Evolvabil- ity, enablement, and emergence.Acta Biotheoretica, 60(4):379–392, 2012

2012

[16] [16]

Maturana and Francisco J

Humberto R. Maturana and Francisco J. Varela.Autopoiesis and Cognition: The Realization of the Living. D. Reidel Publishing Company, Dordrecht, 1980

1980

[17] [17]

Varela.Principles of Biological Autonomy

Francisco J. Varela.Principles of Biological Autonomy. North-Holland, New York, 1979

1979

[18] [18]

The computational boundary of a “self”: developmental bioelectricity drives multicellularity and scale-free cognition.Frontiers in psychology, 10:493866, 2019

Michael Levin. The computational boundary of a “self”: developmental bioelectricity drives multicellularity and scale-free cognition.Frontiers in psychology, 10:493866, 2019. 20

2019

[19] [19]

Michael Levin. Life, death, and self: Fundamental questions of primitive cognition viewed through the lens of body plasticity and synthetic organisms.Biochemical and Biophysical Re- search Communications, 564:114–133, 2021

2021

[20] [20]

Artificial life: organization, adaptation and complexity from the bottom up

Mark A Bedau. Artificial life: organization, adaptation and complexity from the bottom up. Trends in cognitive sciences, 7(11):505–512, 2003

2003

[21] [21]

Adam Smith.An Inquiry into the Nature and Causes of the Wealth of Nations. W. Strahan and T. Cadell, London, 1776

[22] [22]

Friedrich A. Hayek. The use of knowledge in society.The American Economic Review, 35(4):519– 530, 1945

1945

[23] [23]

Borgatti and Martin G

Stephen P. Borgatti and Martin G. Everett. Models of core/periphery structures.Social Net- works, 21(4):375–395, 1999

1999

[24] [24]

Structure and dynamics of core/periphery networks.Journal of Complex Networks, 1(2):93–123, 2013

Peter Csermely, Andras London, Ling-Yun Wu, and Brian Uzzi. Structure and dynamics of core/periphery networks.Journal of Complex Networks, 1(2):93–123, 2013

2013

[25] [25]

Brian Arthur

W. Brian Arthur. Foundations of complexity economics.Nature Reviews Physics, 3:136–145, 2021

2021

[26] [26]

Agent-based computational economics: Growing economies from the bottom up.Artificial Life, 8(1):55–82, 2002

Leigh Tesfatsion. Agent-based computational economics: Growing economies from the bottom up.Artificial Life, 8(1):55–82, 2002

2002

[27] [27]

Epstein and Robert Axtell.Growing Artificial Societies: Social Science from the Bottom Up

Joshua M. Epstein and Robert Axtell.Growing Artificial Societies: Social Science from the Bottom Up. MIT Press, Cambridge, MA, 1996

1996

[28] [28]

Stephen Jay Gould and Elisabeth S. Vrba. Exaptation–a missing term in the science of form. Paleobiology, 8(1):4–15, 1982

1982

[29] [29]

Kauffman.Investigations

Stuart A. Kauffman.Investigations. Oxford University Press, New York, 2000

2000

[30] [30]

Brian Arthur.The Nature of Technology: What It Is and How It Evolves

W. Brian Arthur.The Nature of Technology: What It Is and How It Evolves. Free Press, New York, 2009

2009

[31] [31]

echo state

Herbert Jaeger. The “echo state” approach to analysing and training recurrent neural networks- with an erratum note.Bonn, Germany: German National Research Center for Information Technology GMD Technical Report, 148(34):13, 2001

2001

[32] [32]

Real-time computing without stable states: A new framework for neural computation based on perturbations.Neural compu- tation, 14(11):2531–2560, 2002

Wolfgang Maass, Thomas Natschl¨ ager, and Henry Markram. Real-time computing without stable states: A new framework for neural computation based on perturbations.Neural compu- tation, 14(11):2531–2560, 2002

2002

[33] [33]

Reservoir computing approaches to recurrent neural network training.Computer Science Review, 3(3):127–149, 2009

Mantas Lukoˇ seviˇ cius and Herbert Jaeger. Reservoir computing approaches to recurrent neural network training.Computer Science Review, 3(3):127–149, 2009

2009

[34] [34]

Analysis of structure and dynamics in three-neuron motifs.Frontiers in Computational Neuroscience, 13:5, 2019

Patrick Krauss, Alexandra Zankl, Achim Schilling, Holger Schulze, and Claus Metzner. Analysis of structure and dynamics in three-neuron motifs.Frontiers in Computational Neuroscience, 13:5, 2019

2019

[35] [35]

Recurrence resonance” in three-neuron motifs.Frontiers in computational neuroscience, 13, 2019

Patrick Krauss, Karin Prebeck, Achim Schilling, and Claus Metzner. Recurrence resonance” in three-neuron motifs.Frontiers in computational neuroscience, 13, 2019

2019

[36] [36]

Weight statistics controls dynamics in recurrent neural networks.PloS one, 14(4):e0214541, 2019

Patrick Krauss, Marc Schuster, Verena Dietrich, Achim Schilling, Holger Schulze, and Claus Met- zner. Weight statistics controls dynamics in recurrent neural networks.PloS one, 14(4):e0214541, 2019. 21

2019

[37] [37]

Dynamical phases and resonance phenomena in information- processing recurrent neural networks.arXiv preprint arXiv:2108.02545, 2021

Claus Metzner and Patrick Krauss. Dynamical phases and resonance phenomena in information- processing recurrent neural networks.arXiv preprint arXiv:2108.02545, 2021

arXiv 2021

[38] [38]

Dynamics and information import in recurrent neural net- works.Frontiers in Computational Neuroscience, 16, 2022

Claus Metzner and Patrick Krauss. Dynamics and information import in recurrent neural net- works.Frontiers in Computational Neuroscience, 16, 2022

2022

[39] [39]

Quan- tifying and maximizing the information flux in recurrent neural networks.Neural Computation, 36(3):351–384, 2024

Claus Metzner, Marius E Yamakou, Dennis Voelkl, Achim Schilling, and Patrick Krauss. Quan- tifying and maximizing the information flux in recurrent neural networks.Neural Computation, 36(3):351–384, 2024

2024

[40] [40]

Recurrence resonance- noise-enhanced dynamics in recurrent neural networks.Frontiers in Complex Systems, 2:1479417, 2024

Claus Metzner, Achim Schilling, Andreas Maier, and Patrick Krauss. Recurrence resonance- noise-enhanced dynamics in recurrent neural networks.Frontiers in Complex Systems, 2:1479417, 2024

2024

[41] [41]

Nonlinear neural dynamics and classification accuracy in reservoir computing.Neural Computation, 37(8):1469–1504, 2025

Claus Metzner, Achim Schilling, Andreas Maier, and Patrick Krauss. Nonlinear neural dynamics and classification accuracy in reservoir computing.Neural Computation, 37(8):1469–1504, 2025

2025

[42] [42]

Organizational regularities in recurrent neural networks.Frontiers in Complex Systems, 3:1636222, 2025

Claus Metzner, Achim Schilling, Andreas Maier, and Patrick Krauss. Organizational regularities in recurrent neural networks.Frontiers in Complex Systems, 3:1636222, 2025

2025

[43] [43]

Sorn: a self-organizing recurrent neural network.Frontiers in Computational Neuroscience, 3:23, 2009

Andreea Lazar, Gordon Pipa, and Jochen Triesch. Sorn: a self-organizing recurrent neural network.Frontiers in Computational Neuroscience, 3:23, 2009

2009

[44] [44]

Rumelhart, Geoffrey E

David E. Rumelhart, Geoffrey E. Hinton, and Ronald J. Williams. Learning representations by back-propagating errors.Nature, 323(6088):533–536, 1986

1986

[45] [45]

Surviving by Serv- ing

Yann LeCun, Yoshua Bengio, and Geoffrey Hinton. Deep learning.nature, 521(7553):436–444, 2015. 22 output input agent function/ product reward (a) (b) Figure 1:Main idea and adaptive interaction network. (a)Principle of “Surviving by Serv- ing”: Components or agents (green) receive local reinforcement signals (blue) when their outputs, functions, or states...

2015