Difference between revisions of "Particle Swarm Optimization - Scholarpedia Draft"
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Revision as of 17:55, 22 October 2008
Particle swarm optimization (PSO) is a population-based stochastic approach for solving continuous and discrete optimization problems.
In particle swarm optimization, simple software agents, called particles, move in the solution space of an optimization problem. The position of a particle represents a candidate solution to the optimization problem at hand. Particles search for better positions in the solution space by changing their velocity according to rules originally inspired by behavioral models of bird flocking.
Particle swarm optimization belongs to the class of swarm intelligence techniques that are used to solve optimization problems.
History
Particle swarm optimization was introduced by Kennedy and Eberhart (1995). It has roots in the simulation of social behaviors using tools and ideas taken from computer graphics and social psychology research.
Within the field of computer graphics, the first antecedents of particle swarm optimization can be traced back to the work of Reeves (1983), who proposed particle systems to model objects that are dynamic and cannot be easily represented by polygons or surfaces. Examples of such objects are fire, smoke, water and clouds. In these models, particles are independent of each other and their movement is governed by a set of rules. Some years later, Reynolds (1987) used a particle system to simulate the collective behavior of a flock of birds. In a similar kind of simulation, Heppner and Grenander (1990) included a roost that was attractive to the simulated birds. Both models inspired the set of rules that were later used in the original particle swarm optimization algorithm.
Social psychology research was another source of inspiration in the development of the first particle swarm optimization algorithm. The rules that govern the movement of the particles in a problem's solution space can also be seen as a model of human social behavior in which individuals adjust their beliefs and attitudes to conform with those of their peers (Kennedy & Eberhart 1995).
Standard PSO algorithm
Preliminaries
The problem of minimizing <ref name="minimization">Without loss of generality, the presentation considers only minimization problems.</ref> the function <math>f: \Theta \to \mathbb{R}</math> with <math>\Theta \subseteq \mathbb{R}^n</math> can be stated as finding the set
<math>\Theta^* = \underset{\vec{\theta} \in \Theta}{\operatorname{arg\,min}} \, f(\vec{\theta}) = \{ \vec{\theta}^* \in \Theta \colon f(\vec{\theta}^*) \leq f(\vec{\theta}), \,\,\,\,\,\,\forall \vec{\theta} \in \Theta\}\,,</math>
where <math>\vec{\theta}</math> is an <math>n</math>-dimensional vector that belongs to the set of feasible solutions <math>\Theta</math> (also called solution space).
In PSO, the so-called swarm is composed of a set of particles <math>\mathcal{P} = \{p_{1},p_{2},\ldots,p_{k}\}</math>. A particle's position represents a candidate solution of the considered optimization problem represented by an objective function <math>f</math>. At any time step <math>t</math>, <math>p_i</math> has a position <math>\vec{x}^{\,t}_i</math> and a velocity <math>\vec{v}^{\,t}_i</math> associated to it. The best position that particle <math>p_i</math> (with respect to <math>f</math>) has ever visited until time step <math>t</math> is represented by vector <math>\vec{b}^{\,t}_i</math> (also known as a particle's personal best). Moreover, a particle <math>p_i</math> receives information from its neighborhood <math>\mathcal{N}_i \subseteq \mathcal{P}</math>. In the standard particle swarm optimization algorithm, the particles' neighborhood relations are commonly represented as a graph <math>G=\{V,E\}</math>, where each vertex in <math>V</math> corresponds to a particle in the swarm and each edge in <math>E</math> establishes a neighbor relation between a pair of particles. The resulting graph is commonly referred to as the swarm's population topology.
The algorithm
The PSO algorithm starts with the random generation of the particles' positions within an initialization region <math>\Theta^\prime \subseteq \Theta</math>. Velocities are usually initialized to zero, but can be initialized to small random values. During the main loop of the algorithm, the particles' velocities and positions are iteratively updated until a stopping criterion is met.
The update rules are:
<math>\vec{v}^{\,t+1}_i = w\vec{v}^{\,t}_i + \varphi_2\vec{U}^{\,t}_1(\vec{b}^{\,t}_i - \vec{x}^{\,t}_i) + \varphi_2\vec{U}^{\,t}_2(\vec{l}^{\,t}_i - \vec{x}^{\,t}_i) \,,</math>
<math>\vec{x}^{\,t+1}_i = \vec{x}^{\,t}_i +\vec{v}^{\,t+1}_i \,,</math>
where <math>w</math> is a parameter called inertia weight, <math>\varphi_1</math> and <math>\varphi_2</math> are two parameters called acceleration coefficients, <math>\vec{U}^{\,t}_1</math> and <math>\vec{U}^{\,t}_2</math> are two <math>n \times n</math> diagonal matrices in which the entries in the main diagonal are distributed in the interval <math>[0,1)\,</math> uniformly at random. At every iteration, these matrices are regenerated, that is, <math>\vec{U}^{\,t+1}_{1,2} \neq \vec{U}^{\,t}_{1,2}</math>. Usually, vector <math>\vec{l}^{\,t}_i</math>, referred to as the neighborhood best, is the best position ever found by any particle in the neighborhood of particle <math>p_i</math>, that is, <math>f(\vec{l}^{\,t}_i) \leq f(\vec{b}^{\,t}_j) \,\,\, \forall p_j \in \mathcal{N}_i</math>. Alternatively, the neighborhood best can be selected as the current best particle, that is, <math>f(\vec{l}^{\,t}_i) \leq f(\vec{x}^{\,t}_j) \,\,\, \forall p_j \in \mathcal{N}_i</math>. If the values of <math>w</math>, <math>\varphi_1</math> and <math>\varphi_2</math> are properly chosen, it is guaranteed that the particles' velocities do not grow to infinity (Clerc and Kennedy 2002).
The three terms in the velocity update rule characterizes the local, simple behaviors that particles follow. The first term, called the inertia or momentum serves as a memory of the previous flight direction, preventing the particle from drastically changing direction. The second term, called the cognitive component resembles the tendency of particles to return to previously found best positions. The third term, called the social component quantifies the performance of a particle relative to its neighbors. It represents a group norm or standard that should be attained.
A pseudocode version of the standard PSO algorithm is shown below:
:Inputs Objective function <math>f:\Theta \to \mathbb{R}</math>, the initialization domain <math>\Theta^\prime \subseteq \Theta</math>,
the number of particles <math>|\mathcal{P}| = k</math>, the parameters <math>w</math>, <math>\varphi_1</math>, and <math>\varphi_2</math>, and the stopping criterion <math>S</math>
:Output Best solution found
// Initialization
Set t := 0
for i := 1 to k do
Initialize <math>\mathcal{N}_i</math> to a subset of <math>\mathcal{P}</math> according to the desired topology
Initialize <math>\vec{x}^{\,t}_i</math> randomly within <math>\Theta^\prime</math>
Initialize <math>\vec{v}^{\,t}_i</math> to zero or small random values
Set <math>\vec{b}^{\,t}_i = \vec{x}^{\,t}_i</math>
end for
// Main loop
while <math>S</math> is not satisfied do
// Velocity and position update loop
for i := 1 to k do
Set <math>\vec{l}^{\,t}_i</math> := <math>\underset{{\vec{b}^{\,t}}_j \in \Theta \,|\, p_j \in \mathcal{N}_i}{\operatorname{arg\,min}} \, f({\vec{b}^{\,t}}_j)</math>
Generate random matrices <math>\vec{U}^{\,t}_1</math> and <math>\vec{U}^{\,t}_2</math>
Set <math>\vec{v}^{\,t+1}_i</math> := <math>w\vec{v}^{\,t}_i + \varphi_1\vec{U}^{\,t}_1(\vec{b}^{\,t}_i - \vec{x}^{\,t}_i) + \varphi_2\vec{U}^{\,t}_2(\vec{l}^{\,t}_i - \vec{x}^{\,t}_i)</math>
Set <math>\vec{x}^{\,t+1}_i</math> := <math>\vec{x}^{\,t}_i + \vec{v}^{\,t+1}_i</math>
end for
// Solution update loop
for i := 1 to k do
if <math>f(\vec{x}^{\,t}_i) < f(\vec{b}^{\,t}_i)</math>
Set <math>\vec{b}^{\,t}_i</math> := <math>\vec{x}^{\,t}_i</math>
end if
end for
Set t := t + 1
end while
The algorithm above follows synchronous updates of particle positions and best positions, where the best position found is updated only after all particle positions and personal best positions have been updated. In asynchronous update mode, the best position found is updated immediately after each particle's position update. Asynchronous updates have a faster propagation of best solutions through the swarm.
Main PSO variants
The original particle swarm optimization algorithm has undergone a number of changes since it was first proposed. Most of these changes affect the way the particles' velocity is updated. In the following subsections, we briefly describe some of the most important developments. For a more detailed description of many of the existing particle swarm optimization variants, see (Kennedy and Eberhart 2001, Engelbrecht 2005, Clerc 2006 and Poli et al. 2007).
Discrete PSO
Most particle swarm optimization algorithms are designed to search in continuous domains. However, there are a number of variants that operate in discrete spaces. The first variant that worked on discrete domains was the binary particle swarm optimization algorithm (Kennedy and Eberhart 1997). In this algorithm, a particle's position is discrete but its velocity is continuous. The <math>j</math>th component of a particle's velocity vector is used to compute the probability with which the <math>j</math>th component of the particle's position vector takes a value of 1. Velocities are updated as in the standard PSO algorithm, but positions are updated using the following rule
<math> x^{t+1}_{ij} = \begin{cases} 1 & \mbox{if } r < sig(v^{t+1}_{ij}),\\ 0 & \mbox{otherwise,} \end{cases} </math> where <math>x_{ij}</math> is the <math>j</math>th component of the position vector of particle <math>p_i</math>, <math>r</math> is a uniformly distributed random number in the range <math>[0,1)\,</math> and
<math> sig(x) = \frac{1}{1+e^{-x}}\,. </math>
Constriction Coefficient
The constriction coefficient was introduced as an outcome of a theoretical analysis of swarm dynamics (Clerc and Kennedy 2002). Velocities are constricted, with the following change in the velocity update: <math>\vec{v}^{\,t+1}_i = \chi^t[\vec{v}^{\,t}_i + \varphi_2\vec{U}^{\,t}_1(\vec{b}^{\,t}_i - \vec{x}^{\,t}_i) + \varphi_2\vec{U}^{\,t}_2(\vec{l}^{\,t}_i - \vec{x}^{\,t}_i)]</math> where <math>\chi^t</math> is an <math>n \times n</math> diagonal matrix in which the entries in the main diagonal are calculated as
<math>\chi^t_{jj}=\frac{2\kappa}{|2-\varphi^t_{jj}-\sqrt{\varphi^t_{jj}(\varphi^t_{jj}-2)}|}</math> with <math>\varphi^t_{jj}=\varphi_1U^t_{1,jj}+\varphi_2U^t_{2,jj}</math>. Convergence is guaranteed under the conditions that <math>\varphi^t_{jj}\ge 4\,\forall j</math> and <math>\kappa\in [0,1]</math>.
Bare bones PSO
The bare-bones particle swarm (Kennedy 2003) is a variant of the particle swarm optimization algorithm in which the velocity- and position-update rules are substituted by a procedure that samples a parametric probability density function.
In the bare-bones particle swarm optimization algorithm, a particle's position update rule in the <math>j</math>th dimension is <math> x^{t+1}_{ij} = N\left(\mu^{t} ,\sigma^{\,t}\right)\,, </math> where <math>N</math> is a normal distribution with
<math> \begin{array}{ccc} \mu^{t} &=& \frac{b^{t}_{ij} + l^{t}_{ij}}{2} \,, \\ \sigma^{t} & = & |b^{t}_{ij} - l^{t}_{ij}| \,. \end{array} </math>
Fully informed PSO
In the standard particle swarm optimization algorithm, a particle is attracted toward its best neighbor. A variant in which a particle uses the information provided by all its neighbors in order to update its velocity is called the fully informed particle swarm (FIPS) (Mendes et al. 2004).
In the fully informed particle swarm optimization algorithm, the velocity-update rule is
<math> \vec{v}^{\,t+1}_i = w\vec{v}^{\,t}_i + \frac{\varphi}{|\mathcal{N}_i|}\sum_{p_j \in \mathcal{N}_i}\mathcal{W}(\vec{b}^{\,t}_j)\vec{U}^{\,t}_j(\vec{b}^{\,t}_j-\vec{x}^{\,t}_i) \,, </math> where <math>\mathcal{W} \colon \Theta \to [0,1]</math> is a function that weighs the contribution of a particle's personal best position to the movement of the target particle based on its relative quality.
Applications of PSO and Current Trends
The first practical application of a PSO algorithm was in the field of neural network training and was published together with the algorithm itself (Kennedy and Eberhart 1995). Many more areas of application have been explored ever since, including telecommunications, control, data mining, design, combinatorial optimization, power systems, signal processing, and many others. To date, there are hundreds of publications reporting applications of particle swarm optimization algorithms. For a review, see (Poli 2008). Although PSO has been used mainly to solve unconstrained, single-objective optimization problems, PSO algorithms have been developed to solve constrained problems, multi-objective optimization problems, problems with dynamically changing landscapes, and to find multiple solutions. For a review, see (Engelbrecht 2005).
A number of research directions are currently pursued, including:
- Theoretical aspects
- Matching algorithms (or algorithmic components) to problems
- Application to more and/or different kind of problems (e.g., multiobjective)
- Parameter selection
- Comparisons between PSO variants and other algorithms
- New variants
Notes
<references />
References
M. Clerc and J. Kennedy. The particle swarm-explosion, stability and convergence in a multidimensional complex space. IEEE Transactions on Evolutionary Computation, 6(1):58-73, 2002.
M. Clerc. Particle Swarm Optimization. ISTE, London, UK, 2006.
A. P. Engelbrecht. Fundamentals of Computational Swarm Intelligence. John Wiley & Sons, Chichester, UK, 2005.
F. Heppner and U. Grenander. A stochastic nonlinear model for coordinated bird flocks. The Ubiquity of Chaos. AAAS Publications, Washington, DC, 1990.
J. Kennedy. Bare bones particle swarms. In Proceedings of the IEEE Swarm Intelligence Symposium, pages 80-87, IEEE Press, Piscataway, NJ, 2003.
J. Kennedy and R. Eberhart. Particle swarm optimization. In Proceedings of IEEE International Conference on Neural Networks, pages 1942-1948, IEEE Press, Piscataway, NJ, 1995.
J. Kennedy and R. Eberhart. A discrete binary version of the particle swarm algorithm. In Proceedings of the IEEE International Conference on Systems, Man and Cybernetics, pages 4104-4108, IEEE Press, Piscataway, NJ, 1997.
J. Kennedy, and R. Eberhart. Swarm Intelligence. Morgan Kaufmann, San Francisco, CA, 2001.
R. Mendes, J. Kennedy, and J. Neves. The fully informed particle swarm: simpler, maybe better. IEEE Transactions on Evolutionary Computation, 8(3):204-210, 2004.
R. Poli. Analysis of the publications on the applications of particle swarm optimisation. Journal of Artificial Evolution and Applications, Article ID 685175, 10 pages, 2008.
R. Poli, J. Kennedy, and T. Blackwell. Particle swarm optimization. An overview. Swarm Intelligence, 1(1):33-57, 2007.
W. T. Reeves. Particle systems-a technique for modeling a class of fuzzy objects. ACM Transactions on Graphics, 2(2):91-108, 1983.
C. W. Reynolds. Flocks, herds, and schools: A distributed behavioral model. ACM Computer Graphics,21(4):25-34, 1987.
External Links
- Papers on PSO are published regularly in many journals and conferences:
- The main journal reporting research on PSO is Swarm Intelligence. Other journals also publish articles about PSO. These include the IEEE Transactions series, Natural Computing, Structural and Multidisciplinary Optimization, Soft Computing and others.
- ANTS - International Conference on Swarm Intelligence, started in 1998.
- The IEEE Swarm Intelligence Symposia, started in 2003.
- Special sessions or special tracks on PSO are organized in many conferences. Examples are the IEEE Congress on Evolutionary Computation (CEC) and the Genetic and Evolutionary Computation (GECCO) series of conferences.
- Papers on PSO are also published in the proceedings of many other conferences such as Parallel Problem Solving from Nature conferences, the European Workshops on the Applications of Evolutionary Computation and many others.
See also
Optimization, Stochastic Optimization, Swarm Intelligence, Ant Colony Optimization