Dynamical Systems And Chaos: The Bifurcation Diagram Part 1
These are videos form the online course ‘Introduction to Dynamical Systems and Chaos’ hosted on Complexity Explorer. With these videos you'll gain an introduction to the modern study of dynamical systems, the interdisciplinary field of applied mathematics that studies systems that change over time.
Topics to be covered include: phase space, bifurcations, chaos, the butterfly effect, strange attractors, and pattern formation. The course will focus on some of the realizations from the study of dynamical systems that are of particular relevance to complex systems:
1. Dynamical systems undergo bifurcations, where a small change in a system parameter such as the temperature or the harvest rate in a fishery leads to a large and qualitative change in the system's behavior.
2. Deterministic dynamical systems can behave randomly. This property, known as sensitive dependence or the butterfly effect, places strong limits on our ability to predict some phenomena.
3. Disordered behavior can be stable. Non-periodic systems with the butterfly effect can have stable average properties. So the average or statistical properties of a system can be predictable, even if its details are not.
4. Complex behavior can arise from simple rules. Simple dynamical systems do not necessarily lead to simple results. In particular, we will see that simple rules can produce patterns and structures of surprising complexity.
Help us caption & translate this video!
http://amara.org/v/D7Ln/
Видео Dynamical Systems And Chaos: The Bifurcation Diagram Part 1 канала Complexity Explorer
Topics to be covered include: phase space, bifurcations, chaos, the butterfly effect, strange attractors, and pattern formation. The course will focus on some of the realizations from the study of dynamical systems that are of particular relevance to complex systems:
1. Dynamical systems undergo bifurcations, where a small change in a system parameter such as the temperature or the harvest rate in a fishery leads to a large and qualitative change in the system's behavior.
2. Deterministic dynamical systems can behave randomly. This property, known as sensitive dependence or the butterfly effect, places strong limits on our ability to predict some phenomena.
3. Disordered behavior can be stable. Non-periodic systems with the butterfly effect can have stable average properties. So the average or statistical properties of a system can be predictable, even if its details are not.
4. Complex behavior can arise from simple rules. Simple dynamical systems do not necessarily lead to simple results. In particular, we will see that simple rules can produce patterns and structures of surprising complexity.
Help us caption & translate this video!
http://amara.org/v/D7Ln/
Видео Dynamical Systems And Chaos: The Bifurcation Diagram Part 1 канала Complexity Explorer
Показать
Комментарии отсутствуют
Информация о видео
Другие видео канала
Dynamical Systems And Chaos: The Bifurcation Diagram Part 2
Nonlinear Dynamics: Feigenbaum and Universality
Introducing Bifurcations: The Saddle Node Bifurcation
Phase Transitions & Bifurcations
This equation will change how you see the world (the logistic map)
The Feigenbaum Constant (4.669) - Numberphile
Supercritical and Subcritical Pitchfork Bifurcations | Nonlinear Dynamics and Chaos
Concepts of Bifurcation: Introduction
Chaos Game - Numberphile
What's a Tensor?
Dynamical Systems And Chaos: Iterating the Logistic Equation Part 1
What will happen next? Chaos, mathematics and lemmings | Marcus du Sautoy | TEDxWhitehall
Lyapunov exponents and chaotic dynamics
Understanding Anti-lock Braking System (ABS) !
Using XPPAUT to create a bifurcation diagram for a substrate-depletion model
Bifurcation Theory
Dynamical Systems And Chaos: Bifurcation Diagrams
Steven Strogatz - Nonlinear Dynamics and Chaos: Part 5
Introduction to Complexity: Period Doubling Route to Chaos Part 2