1 / 47

Evolution of Complex Systems

Evolution of Complex Systems. Lecture 12: The Evolution of Science Peter Andras / Bruce Charlton peter.andras@ncl.ac.uk bruce.charlton@ncl.ac.uk. Objectives. Science as a system Origins of science Memory, information subsystem and identity Specialisation and expansion

adamdaniel
Download Presentation

Evolution of Complex Systems

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Evolution of Complex Systems Lecture 12: The Evolution of Science Peter Andras / Bruce Charlton peter.andras@ncl.ac.uk bruce.charlton@ncl.ac.uk

  2. Objectives • Science as a system • Origins of science • Memory, information subsystem and identity • Specialisation and expansion • Interpenetration and expansion • Competition and selection • Emerging sciences

  3. Society • System of human communications • Spoken, written, electronic communications

  4. Science • System of communications about conclusions (continuations) that can be checked experimentally • Two sequence of communications that should lead to the same continuations

  5. Science and religion • Religion: system of un-common knowledge • Religion and science compete to explain perceptions of the society

  6. Science and education • Education: the specialist reproduction subsystem of the society • Science is reproduced by education  higher education

  7. Ancient science • Greeks • Romans • Chinese • Indians • Islam world

  8. Early Christian science • Middle ages • Relatively primitive

  9. Uncommon knowledge • Religion: explaining what is unexplainable in terms of common language

  10. Practical knowledge • Common knowledge about practical problems • Specialist practical knowledge  expansion • E.g., masonry, surgery

  11. Writing and uncommon knowledge • Written communications • Preservation of communications for later reference  memory • Interpretation in new context  memory processing  information subsystem

  12. Systematic uncommon knowledge • Analysing uncommon knowledge • Writing allows longer derivations • Contradictions are found and solved and the solutions are written down • Note: monotheism  simplification  expansion  elaborate uncommon knowledge

  13. Science of uncommon knowledge • Theology: analysis, interpretation and continuation of uncommon knowledge • Schools of theology: monasteries

  14. Writing and practical knowledge • Written communications about practical knowledge • Writing allows longer sequences of continuing communications • Contradictions and solutions are found

  15. Science of practical knowledge • Systematic organization of practical knowledge • E.g., ancient medicine, geometry, masonry, geography, botany textbooks • Schools of practical knowledge: ancient philosophy schools, writing schools in China

  16. The logic of science • Truth • What is true and what is not true (false) according to the rules of the systematic knowledge (early science)  identity of the science

  17. Early sciences as subsystems • Uncommon and practical systematic knowledge systems • Subsystems of the corresponding knowledge system • Defining logic (identity): scientifically true / false

  18. Education • Reproduction of the society – common knowledge base • Family education, religious education, practical knowledge education

  19. Education and theology • Formalized education of uncommon knowledge to reproduce the early science of theology • More need in case of more extended uncommon knowledge systems (e.g., those built by monotheist religions)

  20. Interpenetration: education and theology • New rules of education in conformity with the religion / theology • New system: formal education • Formal education and theology: systematic reproduction and extension of theology  university

  21. Interpenetration: formal education and practical knowledge • Similarities: written communications, analysis, testing of conclusions • Practical sciences change the contents of education (new communication rules) • Education of practical sciences: geometry, botany, geography, astrology

  22. Interpenetration: experimental validation • Practical sciences: experimental validation • Science: truth checking by experimental validation

  23. Science emerging • Boundary between practical sciences, theology, education • New system emerges: science with experimentally validated truth check

  24. Science of law • Practical law practice • Science of law • More variable than theology • Early universities

  25. Science of medicine • Practical anatomy, botany, surgery and theology • Science of medicine – experimental checks • Early universities

  26. Philosophy • Ancient schools – early philosophy • Pure theology free of religion – interfacing with practical sciences • Early universities

  27. Natural philosophy • Practical sciences (geometry, mechanics, astrology, alchemy, geography) and philosophy • Experimentally validated science • 16th – 18th century univerisities

  28. Printing • Reproduction of written text in large amount • Large scale availability of memory for science communications  expansion of the information subsystem of science = more possible to process memories of earlier scientific communications • Explosive expansion of science

  29. Subsystems of natural philosophy • Mathematics, physics, chemistry, astronomy • Specialist languages emerge, which define new subsystems

  30. The environment of science • Society • Science is about the society and its environment

  31. Competing sciences • Alchemy and chemistry • Astrology and astronomy • Competition: which makes better predictions and causes fewer contradictions by making false predictions • Contradictions (identity violations) cause cutting back and reduce growth

  32. Selection of sciences • Sciences which grow faster are selected by the environment • E.g., chemistry against alchemy, astronomy against astrology

  33. Various formalisms • 17th – 18th century mathematics, physics • Each school / scientist had its own formalism

  34. Uniform formalism • 19th century standardisation of mathematics formalism • Simplification and expansion • Interpenetration of mathematics and physics  uniform formalism for physics  expansion of physics

  35. Ways of expansion • Fast expansion at beginning: building the new long descriptions (sequences of continuing communications) • Slow expansion later: gap filling

  36. New subsystems • Structure imposed on communications • Institutional organisation: questioning the identity/existence – conferences, academic departments, scientific societies, journals • New subsystems emerge

  37. Interactions of systems • Interface of sciences • Change of rules • Change of boundaries • Questioning of interface systems  new interface sciences – new identity • E.g., theoretical biology

  38. Other sciences: social sciences • Social philosophy  science of the society • Branches: economics, political science, sociology, psychology (individual communications)

  39. Other sciences: humanities • Interfaces of philosophy with arts: literature, fine arts, music • Integrated older sciences: philosophy, law

  40. Other sciences: engineering • Interfaces of natural sciences (descendants of natural philosophy) and practical sciences: e.g., construction engineering, automotive engineering, mechanical engineering

  41. Medical sciences • Descendants of the science of medicine • E.g., neurology, dentistry, cardiology

  42. New sciences: computer science • Computer science: the science of describing and solving problems • Information sciences – the science of information systems

  43. Summary – 1 • Origins of science • Early sciences: early theology, early practical sciences • Theology • Law, medicine, philosophy, natural philosophy • Memory, information subsystem and identity

  44. Summary – 2 • Interpenetration and interface sciences • Branches of natural philosophy • Competition and selection of sciences • Simplification and expansion of mathematics and physics • Other sciences • New sciences

  45. Q&A – 1 • Is it true that theology was one of the early sciences ? • Is it true that early theology was a subsystem of religion ? • Is it true that the interpenetration of education by theology led to the emergence of formal education ?

  46. Q&A – 2 4. Is it true that the sciences of medicine and law emerged independently from theology ? 5. Is it true that philosophy emerged at the interface of theology and practical sciences ? 6. Is it true that natural philosophy emerged at the interface of medicine and philosophy ? 7. Is it true that astrology competed with mathematics ?

  47. Q&A – 3 8. Is it true that alchemy was out competed by chemistry because the former produced more contradictions reducing its expansion capacity ? 9. Is it true that major expansion of mathematics happened before the uniformisation of mathematical terminology ? 10. Is it true that social sciences developed as descendants of social philosophy ? 11. Is it true that computer science is a new science of problem and solution formulation ? Is it true that it can be seen as a new kind of philosophy ?

More Related