1 / 17

Punctuated Equilibrium and Criticality on Network Structures

Punctuated Equilibrium and Criticality on Network Structures. I. Introduction II. Random Neighbor Model III. BS Evolution Model on Network Structures IV. Results V. Summary. Sungmin Lee, Yup Kim Kyung Hee Univ. I. Introduction. The "punctuated equilibrium" theory.

prentice
Télécharger la présentation

Punctuated Equilibrium and Criticality on Network Structures

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. Punctuated Equilibrium and Criticality on Network Structures I. Introduction II. Random Neighbor Model III. BS Evolution Model on Network Structures IV. Results V. Summary Sungmin Lee, Yup Kim Kyung Hee Univ.

  2. I. Introduction The "punctuated equilibrium" theory Instead of a slow, continuous movement, evolution tends to be characterized by long periods of virtual standstill ("equilibrium"), "punctuated" by episodes Of very fast development of new forms S.J.Gould (1972) Self-organized critical steady state

  3. Fitness - An entire species is represented by a single fitness - The ability of species to survive - The fitness of each species is affected by other species to which it is coupled in the ecosystem. The Bak-Sneppen evolution model P.Bak and K.sneppen PRL 71,4083 (1993) Lowest fitness PBC At each time step, the ecology is updated by (i) locating the site with the lowest fitness and mutating it by assigning a new random number to that site, and (ii) changing the landscapes of the two neighbors by assigning new random numbers to those sites New lowest fitness Snapshot of the stationary state M.Paczuski, S.Maslov, P.Bak PRE 53,414 (1996)

  4. Gap and Critical fitness : The lowest fitness at step s

  5. Punctuated equilibria - long periods of passivity interrupted by sudden bursts of activity The activity versus time in a local segment of ten consecutive sites. Avalanche - subsequent sequences of mutations through fitness below a certain threshold Distribution of avalanche sizes in the critical state

  6. Motivation of this study (1) biospecies 의 연관구조가 Scale-free Network 나 Random Network 일 때 evolution의 특성 연구 (2) Evolution and Punctuated Equilibrium 의 Network structures 에서의 Self-Organized Criticality (3) What is the best structure for the adaptation of species-correlation? (Is there evolution-free network?)

  7. : the i-th smallest fitness value : the distribution of all fitness values in the ecology II. Random Neighbor Model Exactly solvable model Lowest fitness New lowest fitness - At each time step, the ecology is updated by (i) locating the node with the lowest fitness and mutating it by assigning a new random number to that site (ii) changing the landscapes of randomly selected K-1 sites by assigning new random numbers to those sites. : the distribution for where

  8. for The limit is necessary to obtain the tree structure. for The evolution equation for Avalanches (1) identifying each burst with a node (2) and each of K new fitness values resulting from a burst - with either a branch rooted in that node (if the fitness value is less than the threshold value) - with a leaf rooted in the same node (if the fitness value is above threshold) 1 0

  9. 0.2 0.2 0.9 0.3 0.9 0.25 0.3 0.25 0.8 0.1 0.62 0.31 0.7 0.7 0.45 0.75 0.98 0.21 0.4 0.4 0.6 0.5 0.6 0.5 III. BS Evolution Model on Network Structures - generate network structures with N nodes - A random fitness equally distributed between 0 and 1, is assigned to each node. - At each time step, the ecology is updated by (i) locating the node with the lowest fitness and mutating it by assigning a new random number to that site (ii) changing the landscapes of the linked neighbors by assigning new random numbers to those nodes.

  10. Mean degree in this work ( logarithmic) Prediction for our model Random network - We predict the critical behavior of random network is similar to random neighbor model. Scale-free network : degree distribution Scale-free network - We predict the critical value is proportional to the fluctuation of degree similar to random network

  11. IV. Results Random Network Mean degree

  12. Scale-free Network Mean degree Logarithmic(?)

  13. Scale-free Network Mean degree

  14. IV. Summary ◆ Random Network ◆ Scale-free Network ◆ On SFN the system is not critical because all species are adapted. ◆ SFN is critical ◆ On SFN the system is critical and it’s behavior is similar to RN. ◆ is similar to Earthquake model on RN. S.Lise and M.Paczuski PRL 88, 228301 (2002)

More Related