- author = "Xinye Cai",
- title = "A multi-objective {GP-PSO} hybrid algorithm for gene regulatory network modeling",
- school = "Department of Electrical and Computer Engineering, Kansas State University",
- year = "2009",
- address = "Manhattan, Kansas, USA",
- month = may,
- keywords = "genetic algorithms, genetic programming, Cartesian Genetic Programming, multi-objective optimization, particle swarm optimization, gene regulatory network modelling, plant breeding simulation, Arabidopsis, NK fitness landscape models",
- isbn13 = "9781109178562",
-
URL = "
http://hdl.handle.net/2097/1492",
-
URL = "http://krex.k-state.edu/dspace/handle/2097/1492",
-
URL = "
http://krex.k-state.edu/dspace/bitstream/handle/2097/1492/xinyecai2009.pdf",
-
URL = "https://search.proquest.com/docview/304911232",
- size = "130 pages",
-
abstract = "Stochastic algorithms are widely used in various
modelling and optimization problems. Evolutionary
algorithms are one class of population-based stochastic
approaches that are inspired from Darwinian
evolutionary theory. A population of candidate
solutions is initialized at the first generation of the
algorithm. Two variation operators, crossover and
mutation, that mimic the real world evolutionary
process, are applied on the population to produce new
solutions from old ones. Selection based on the concept
of survival of the fittest is used to preserve parent
solutions for next generation. Examples of such
algorithms include genetic algorithm (GA) and genetic
programming (GP). Nevertheless, other stochastic
algorithms may be inspired from animals behaviour such
as particle swarm optimization (PSO), which imitates
the cooperation of a flock of birds. In addition,
stochastic algorithms are able to address
multi-objective optimization problems by using the
concept of dominance. Accordingly, a set of solutions
that do not dominate each other will be obtained,
instead of just one best solution.
This thesis proposes a multi-objective GP-PSO hybrid algorithm to recover gene regulatory network models that take environmental data as stimulus input. The algorithm infers a model based on both phenotypic and gene expression data. The proposed approach is able to simultaneously infer network structures and estimate their associated parameters, instead of doing one or the other iteratively as other algorithms need to. In addition, a non-dominated sorting approach and an adaptive histogram method based on the hypergrid strategy are adopted to address convergence and diversity issues in multi-objective optimization. Gene network models obtained from the proposed algorithm are compared to a synthetic network, which mimics key features of Arabidopsis flowering control system, visually and numerically. Data predicted by the model are compared to synthetic data, to verify that they are able to closely approximate the available phenotypic and gene expression data. At the end of this thesis, a novel breeding strategy, termed network assisted selection, is proposed as an extension of our hybrid approach and application of obtained models for plant breeding. Breeding simulations based on network assisted selection are compared to one common breeding strategy, marker assisted selection. The results show that NAS is better both in terms of breeding speed and final phenotypic level",
- notes = "Supervisor Sanjoy Das",
