Random Boolean Network

From CasGroup

'''Random Boolean Networks''' are networks of boolean nodes that can be in one of two possible states, 0 or 1, and whose evolution from one time point to another is governed by simple boolean transition rules. The nodes change their states according to this boolean transition rules that depend on their current states and those of their neighbors. RBNs are closely related to [[Cellular Automata]] (CA) and are used to study [[Complex System|complex systems]]. Both are usually based on local boolean transition functions. In RBNs we have nodes instead of Cells in CA, and connections to remote neighbors instead of a local neighborhood grid as in CA. RBNs and NK Networks have been proposed as a biological model by Stuart Kauffman, see his book "The Origins of Order". == NK Network == An NK-Boolean network is defined as a network of N nodes with connectivity K, where K refers to the maximum number of nodes that regulate some othernode, i.e. each of the N nodes has K inputs and one output. It can be considered as a network of N light bulbs. At every timestep, each bulb changes the state: the light bulbs can only be on or off, and each of the bulbs influences K other bulbs in the network. * [http://www-users.cs.york.ac.uk/susan/cyc/n/nk.htm Applet for NK networks] == Links == Tutorials * [http://www.itee.uq.edu.au/~kaiw/RBN/ RBN Tutorial] from Kai Willadsen * [http://homepages.vub.ac.be/~cgershen/rbn/tut/index.html RBN Tutorial] from Carlos Gershenson arXiv papers * [http://www.arxiv.org/abs/nlin.AO/0408006 Introduction to Random Boolean Networks] from Carlos Gershenson * [http://arxiv.org/abs/nlin/0204062 Boolean Dynamics with Random Couplings] from Leo Kadanoff et al. Wikipedia Pages * Wikipedia page for [http://en.wikipedia.org/wiki/Boolean_network Boolean Network] == Examples == The Finite State Machine (FSM) for the whole boolean network reveals the attractor structures and the basins of attraction. The attractor - if one exists - is a fixed point or a discrete limit cycle. The limit cycle is of course shorter than the total number of states, which is 2^N for N nodes (2^3=8 for 3 nodes). [[Image:RBNExample1.png|left|RBN Examples]] [[Image:RBNExample2.png|left|RBN Examples]]

Return to Random Boolean Network.