Ponencia del curso: "Pensamiento sistémico abierto: en la encrucijada de un mundo complejo", Universidad de León, 15-17 mayo de 2013

1. 4. März 2011 Informationsphilosophie. Information und urbanes Systeme 1
UN ENFOQUE SISTÉMICO DE LA
INNOVACIÓN:
Cosmos, vida, sociedad
Pensamiento Sistémico Abierto: En la encrucijada de un mundo complejo
León, Mayo 2013
José María Díaz Nafría (Universidad de León; HM)
A SYSTEMATIC APPROACH TO
INNOVATION:
Cosmos, Life, Society

2. Un Enfoque Sistémico de la Innovación:
Cosmos, vida, sociedad
Progressive Perspective (Emergence)
“The force, through which the development of the
individual occurs, is the same force, through
which different organizations at the earth come
into existence.” (Kielmayer, c. 1790)
Regressive Perspective (computing the origins)
“What we call nature is a poetry enclosed within a
secrete enigmatic writing. If the enigma were
unveiled, we would recognize the spirit’s Odyssey.”
(Schelling, STI, 1800)
Purpose:
1. Understanding the emergence of new
beings within the world
2. Understanding cosmological evolution as
computation
A Systematic Approach to Innovation: Cosmos, Life, Society 2

3. Does Emergence exists as
something new in nature?
3
• Emergence can be understood as the “real” consequence of
agents’ actions on its own level (Zimmermann & Díaz 2012; Díaz &
Zimmermann 2012)
• Agents can be generalized by extending S. Kauffman’s idea of
autonomous agency as systems capable to perform
thermodynamic cycles (from pre-geometry, to physics, to chemistry,
to biology, to conscious life, to sociality)
• Ontological irreducibility with respect to the parts constituting the
agency: formation of new classicity, which in turn is related to the
rules of interaction/organization (“new order of existence with its
spatial laws of behavior”, Alexander 1920)
A Systematic Approach to Innovation: Cosmos, Life, Society

4. Does Emergence exists as
something new in nature?
4
• It properly requires rephrasing the philosophical concepts of choice
(from an (un)determined set of possibilities), meaning (related to
the sense of beings, ontological disposition of a real being) and
normalization (as combined effect of a critical mass of interacting
parts) throughout the ladder of complexity.
• The fundamental attributes of Energy, Matter and
Information, Structure need also be reviewed as fundamental
elements for the constitution and evolution of systems.
Potentiality
Energy
Information
Actuality
Matter
Structure
A Systematic Approach to Innovation: Cosmos, Life, Society

5. Does Emergence transcend
classical models of computation?
5
• Classical computation model is restricted by Turing’s halting
theorem bzw. Gödel incompleteness (Chaitin), thus it represents a
case of systemic closure, which is indeed needed for the
constitution of an effective agency (for instance, Kuhn’s normal
science). Thus, it properly models closure.
• Emergence can be visualized as the need to overcome the
limitations of an algorithmic closure referred to the relations
governing the system, which in turn can be mapped into Turing
machines as long as they are in normal operation.
A Systematic Approach to Innovation: Cosmos, Life, Society

6. Does Emergence transcend
classical models of computation?
6
• What computation model can better represent real emergence?
i. Quantum computation (Zizzi 2005)
ii. Cellular automata (Wolfram 2002)
iii. Computational ecologies (Mainzer 2004), etc.
• In the human: perception, scientific discovery, etc. requires
creative abductions which represent a most distant case to
classical computing: epistemological emergences.
• How can we rephrase the relation between physics-aesthetics-
ethics?
Physics
Aesthetics
Ethics
A Systematic Approach to Innovation: Cosmos, Life, Society

7. Basic ideas (fundamental agents)
7
We have rephrase the problem in terms of proper agency
1) Generalized Autonomous Agent (S. Kauffman 2000, 2006): system
able to achieve a new closure in a given space of catalytic and work
tasks propagating work out of non-equilibrium states and playing
natural games according to constraints of its environment.
2) For enabling a systematic view of the universe: the fragmented vision
of quantum- and relativistic physics has to be overcome. Thus we set
off from the level of pre-geometry described in terms of spin networks
(R. Penrose) and the related developments of quantum gravity.
• Good candidate: L. Kauffman’s knot theory visualize spin networks as
knots acting on knots to create knots in rich coupled cycles ( metabolisms)
• Braunstein-Gosh-Severi (SVR) entropy allows to put forward generalized
conditions of autonomous agency in the sense of S. Kauffman.
A Systematic Approach to Innovation: Cosmos, Life, Society

8. Basic ideas (Agent’s dynamics)
8
3) Agency dynamics: mapped through game theoretical applications (Szabó &
Fáth 2007); Evolutionary system dynamics: mapped through category theory
(Zimmermann 2011). Utilizing the “skeleton-of-the-universe-view”
(Zimmermann 2004), we can set off from the fundamental level of quantum
gravity: inserting steps of a hierarchy of complexity into the functor diagram
from topological quantum field theory:
4) Fundamental attributes of the universe
Potentiality
ENERGY: to perform work
INFORMATION: to select/utilize
work in the benefit of the
organization of the system
Actuality
MATTER: actualized (stabilized)
energy
STRUCTURE: actualization of the
organization potential
A Systematic Approach to Innovation: Cosmos, Life, Society

9. 9
Generalized concept of information
Generalized 2nd principle of thermodynamics: entropy/information of a closed
system increases
(Potential) information: what the observer ignores about a situation
(Boltzmann) Entropy: what the observer ignores about the
microscopic constitution of a system
Example 0: steam engine
this is a non-self-organizing
systems working for itself,
but for another system
A Systematic Approach to Innovation: Cosmos, Life, Society

10. 10
The Odyssey of Autonomous Agency
(History of innovation)
A Systematic Approach to Innovation: Cosmos, Life, Society

11. 11
The Odyssey of Autonomous Agency
Example 1: spin networks
A Systematic Approach to Innovation: Cosmos, Life, Society

12. 12
Example 2: atom
A Systematic Approach to Innovation: Cosmos, Life, Society
The Odyssey of Autonomous Agency

13. 13
Example 3: planetary system
A Systematic Approach to Innovation: Cosmos, Life, Society
The Odyssey of Autonomous Agency

14. 14
Example 4: proton channels
A Systematic Approach to Innovation: Cosmos, Life, Society
The Odyssey of Autonomous Agency

15. 15
flagellum
nucleolus
nucleus
photoreceptor
chloroplast
contractile vacuole
eyespot
paramylon
pellicle
flagellar
swelling
INFORMATION as potentiality for building constraints and affordances that
enable propagating work
Example 5: Euglenoid cell
A Systematic Approach to Innovation: Cosmos, Life, Society
The Odyssey of Autonomous Agency

16. Basic ideas (observing agent)
16
5) In Cognitive and social contexts, we deal with agents who have self-
reflection and try to reconstruct objective situations from essentially
limited information (Díaz 2011). Basic level: animal perception.
• We introduce: hermeneutical agency (HA), defined in terms of
observation-interpretation cycles (“sensing reality” – Zubiri).
• The HA can be visualized in thermodynamic terms: abductions as
reduction of (apparent) representation complexity (neg-entropy) or
increase in the probability of interpretation with respect to given constraints
(maximal likelihood). Semantics as interpretation tools, which evolves
from the very sense of the being (means to reproducing itself, and to
evolving); from objective- to reflective- response.
• Semantics are only relatively closed. Openness becomes clear when an
epistemic emergence is needed, rooted on ontological constraints (Levy-
Strauss).
A Systematic Approach to Innovation: Cosmos, Life, Society

17. 17
Animal vision
Light
Photoreceptors
Photoreceptors
Neuronalnetwork
Light
Neuronal
network
a) Retina structure of vertebrates b) Retina structure of octopus
A Systematic Approach to Innovation: Cosmos, Life, Society

18. 18
Hermeneutical agency
(computational mapping)
s
N
, Ψ1
N
... ΨN
N
Initial hypothesis
G2
-1
G1
-1
G2G1
Ob{ k
1Ψ }
},{
1kk
d ss
K{ k
s }Ob{ k
2Ψ } Ob{ k
3Ψ } Ob{ k
NΨ }
G3
-1
G 3
GN
-1
G N
● ● ●
Application of
observations
(corresponding to
manifestation of
modality 1, 2,.. )
Gi : allows to derive the
manifestation of modality i from an
interpretation of the object, s.
Gi -1
: allows to make an
interpretation of the object s
consistent with observation i
Truthfulness criterion
Iteration
Interpretation output
A Systematic Approach to Innovation: Cosmos, Life, Society

19. 19
Conclusive remark
• By using the given conceptualization of the fundamental attributes
(E, M, I, S) emergence can be mapped from the pre-geometrical
level to the social one;
• It requires at the fundamental level an unified perspective
(quantum gravity)
• The emergence is visualized as consequence of agent’s action at
its own level causing new classicities (space-time, forces,
particles, molecules, organisms, humans, societies), related to the
rules of interaction/organization.
• Hermeneutical agency requires rephrasing the relation between
physics, ethics and aesthetics (normalization, meaning, choice).
A Systematic Approach to Innovation: Cosmos, Life, Society

20. Is information a sufficient basis for cognition?
20
A SYSTEMATIC APPROACH TO INNOVATION:
Cosmos, Life, Society