This book contains the proceedings of the Seventh National Conference of the Italian Systems Society. The title, Systemics of Incompleteness and Quasi-Systems, aims to underline the need for Systemics and Systems Science to deal with the concepts of incompleteness and quasiness. Classical models of Systemics are intended to represent comprehensive aspects of phenomena and processes. They consider the phenomena in their temporal and spatial completeness. In these cases, possible incompleteness in the modelling is assumed to have a provisional or practical nature, which is still under study, and because there is no theoretical reason why the modelling cannot be complete. In principle, this is a matter of non-complex phenomena, to be considered using the concepts of the First Systemics.
When dealing with emergence, there are phenomena which must be modelled by systems having multiple models, depending on the aspects being taken into consideration. Here, incompleteness in the modelling is intrinsic, theoretically relating changes in properties, structures, and status of system. Rather than consider the same system parametrically changing over time, we consider sequences of systems coherently. We consider contexts and processes for which modelling is incomplete, being related to only some properties, as well as those for which such modelling is theoretically incomplete—as in the case of processes of emergence and for approaches considered by the Second Systemics. In this regard, we consider here the generic concept of quasi explicating such incompleteness. The concept of quasi is used in various disciplines including quasi-crystals, quasi-particles, quasi-electric fields, and quasi-periodicity.
In general, the concept of quasiness for systems concerns their continuous structural changes which are always meta-stable, waiting for events to collapse over other configurations and possible forms of stability; whose equivalence depends on the type of phenomenon under study. Interest in the concept of quasiness is not related to its meaning of rough approximation, but because it indicates an incompleteness which is structurally sufficient to accommodate processes of emergence and sustain coherence or generate new, equivalent or non-equivalent, levels.
The conference was devoted to identifying, discussing and understanding possible interrelationships of theoretical disciplinary improvements, recognised as having prospective fundamental roles for a new Quasi-Systemics. The latter should be able to deal with problems related to complexity in more general and realistic ways, when a system is not always a system and not always the same system. In this context, the inter-disciplinarity should consist, for instance, of a constructionist, incomplete, non-ideological, multiple, contradiction-tolerant, Systemics, always in progress, and in its turn, emergent.
Part I Opening Lectures.
Chapter 1 Interfaces of Incompleteness.-
Chapter 2 First Steps Toward a Systemic Ontology.- Part II Models of
Incompleteness and Quasiness.
Chapter 3 All the Shades of Incompleteness:
the Interesting Case of Structure/Function Relations in Biochemistry.-
Chapter 4 Sentences and Systems.
Chapter 5 Does Systemics still need
Theories? Theory-less Knowledge.- Part III The Concept of Incompleteness and
Quasiness in Science and Philosophy.
Chapter 6 On the Complexity of Baroque
Music and Implications on Robotics and Creativity.
Chapter 7 Music:
Creativity and New Technologies. A Systemic Approach towards Multimedia
Project and Sound Design.
Chapter 8 Architecture and Systemics Performance
Revisited.
Chapter 9 Systemic Ontology and Heideggers Ontology: a
Discussion on Systems and Logos.
Chapter 10 The Idea of Incompleteness in
the Internal Realism of Hilary Putnam.- Part IV Incompleteness and Quasiness
inPost-Bertalanffy Systemics Complexity.
Chapter 11 Are Dynamically
Undecidable Systems Ubiquitous.
Chapter 12 A View of Criticality in the
Ising Model through the Relevance Index.
Chapter 13 An Example of
Quasi-System in the Generation and Transmission of Electrical Power.- Part
V Incompleteness and Quasiness in Social Systems.
Chapter 14 The
Psychopathological Process as a System of Dysfunction and Systemic
Compensation with Top-down Modulation.
Chapter 15 A Note on Variety and
Hierarchy of Economic and Social Systems. The System-Network Dualism and the
Consequences of Routinization and Robotization.
Chapter 16 Information,
Communication Technologies and Regulations.
Chapter 17 Connections and
Dissimilarities among Formal Concept Analysis, Knowledge Space Theory and
Cognitive Diagnostic Models in a Systemic Perspective.
Chapter 18 Theatrical
Organicism: Thoughts on Drama and System Theory.
Chapter 19 A Need for
Systetics.
Chapter 20 A Systemic Approach to Religious Communication: Case
Study of La Luz del Mundo Church.
Chapter 21 Values for Some. How Does
Criminal Network Undermine the Political System? A Data Mining Perspective.-
Part VI Emergence, Quasiness and Incompleteness: Maintaining, Crises
and Degeneration in Emergence Phenomena.
Chapter 22 Embracing the Unknown in
Post-Bertalany Systemics Complexity Modeling.
Chapter 23 The Problem of
Functional Boundaries in Prebiotic and Inter-biological Systems.
Chapter
24 AI-Chatbot Using Deep Learning to Assist the Elderly.
Chapter 25 The Use
of Brain Computer Interface (BCI) Combined with Serious Games for
Pathological Dependence Treatment.
Chapter 26 The Management Complexity of
an Hospital Psychiatric Ward: A Small World Approach.
Chapter 27 Natural
Rates of Teachers Approval and Disapproval in Italian Primary and Secondary
Schools Classroom.
Chapter 28 On Some Open Issues in Systemics.
Gianfranco Minati, Systems scientist, mathematician, Founder and president of the Italian Systems Society (AIRS); President of the European Union for Systemics; Doctoral lecturer at the Polytechnic of Milan; Member of the scientific committee of Conferences and Systems Societies. He is author of 35 chapters in books; editor of 9 books and journals; author or co-author of 15 books; author of 41 articles and of academic publications.
His current research interest focuses on
1) Modelling processes of emergence by using Meta-Structures;
2) the emerging of a Post-Bertalanffy Systemics;
3) the Dynamic Usage of Models (DYSAM), Logical Openness;
4) Architecture and Design as the design of social meta-structures to influence processes of emergence in social systems.
Mario Renato Abram, Physicist, is active in Italian Systems Society (AIRS). He worked mainly in ENEL (Italian Power Agency), at Research Department (Automatica Research Center), then in Cesi S.p.A. and Cesi Ricerca S.p.A. He experienced hybrid and digital simulation systems, working on models of power systems, thermoelectric and nuclear power plants and processes control, development of simulators for testing and tuning supervision and control systems. His research interests include: dynamical systems, neural networks applications, modeling and simulation of processes and interactions between infrastructural networks.
Eliano Pessa, Theoretical Physicist, is actually Full Professor of General Psychology and Cognitive Modeling at the University of Pavia, Italy. He has already been Dean of the Department of Psychology and of the Inter-departmental Research Center on Cognitive Science in the same university. In the past he has been Associate Professor of Artificial Intelligence at the University of Rome La Sapienza, Faculty of Psychology. He is author or co-author of 10 books and of a large number of papers on scientific journals, books, proceedings of international conferences. His scientific research interests include: quantum theories of brain operation, computational neuroscience, artificial neural networks, models of emergence processes, quantum field theory, models of phase transitions in condensed matter, models of human memory and visual perception, models of decision making, models of statistical reasoning.
