On Linear Genetic Programming
Created by W.Langdon from
gp-bibliography.bib Revision:1.8081
- @PhdThesis{B2005OLGP,
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title = "On Linear Genetic Programming",
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author = "Markus Brameier",
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month = feb,
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year = "2004",
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school = "Fachbereich Informatik, Universit{\"a}t Dortmund",
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address = "Germany",
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keywords = "genetic algorithms, genetic programming, Evolutionary
algorithms, Machine learning",
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URL = "https://eldorado.uni-dortmund.de/bitstream/2003/20098/2/Brameierunt.pdf",
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URL = "https://eldorado.uni-dortmund.de/bitstream/2003/20098/1/Brameier.ps",
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size = "272 pages",
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abstract = "The thesis is about linear genetic programming (LGP),
a machine learning approach that evolves computer
programs as sequences of imperative instructions. Two
fundamental differences to the more common tree-based
variant (TGP) may be identified. These are the
graph-based functional structure of linear genetic
programs, on the one hand, and the existence of
structurally noneffective code, on the other hand.The
two major objectives of this work comprise(1) the
development of more advanced methods and variation
operators to produce better and more compact program
solutions and (2) the analysis of general EA/GP
phenomena in linear GP, including intron code, neutral
variations, and code growth, among others.First, we
introduce efficient algorithms for extracting features
of the imperative and functional structure of linear
genetic programs.In doing so, especially the detection
and elimination of noneffective code during runtime
will turn out as a powerful tool to accelerate the
time-consuming step of fitness evaluation in
GP.Variation operators are discussed systematically for
the linear program representation. We will demonstrate
that so called effective instruction mutations achieve
the best performance in terms of solution quality.These
mutations operate only on the (structurally) effective
code and restrict the mutation step size to one
instruction.One possibility to further improve their
performance is to explicitly increase the probability
of neutral variations. As a second, more time-efficient
alternative we explicitly control the mutation step
size on the effective code (effective step
size).Minimum steps do not allow more than one
effective instruction to change its effectiveness
status. That is, only a single node may be connected to
or disconnected from the effective graph component. It
is an interesting phenomenon that, to some extent, the
effective code becomes more robust against destructions
over the generations already implicitly. A special
concern of this thesis is to convince the reader that
there are some serious arguments for using a linear
representation.In a crossover-based comparison LGP has
been found superior to TGP over a set of benchmark
problems. Furthermore, linear solutions turned out to
be more compact than tree solutions due to (1) multiple
usage of subgraph results and (2) implicit parsimony
pressure by structurally noneffective code.The
phenomenon of code growth is analysed for different
linear genetic operators. When applying instruction
mutations exclusively almost only neutral variations
may be held responsible for the emergence and
propagation of intron code. It is noteworthy that
linear genetic programs may not grow if all neutral
variation effects are rejected and if the variation
step size is minimum.For the same reasons effective
instruction mutations realize an implicit complexity
control in linear GP which reduces a possible negative
effect of code growth to a minimum.Another noteworthy
result in this context is that program size is strongly
increased by crossover while it is hardly influenced by
mutation even if step sizes are not explicitly
restricted. Finally, we investigate program teams as
one possibility to increase the dimension of genetic
programs. It will be demonstrated that much more
powerful solutions may be found by teams than by
individuals. Moreover, the complexity of team solutions
remains surprisingly small compared to individual
programs. Both is the result of specialisation and
cooperation of team members.",
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notes = "Day of Submission: 2003-05-28, Committee: Wolfgang
Banzhaf and Martin Riedmiller and Peter Nordin.
\onlineAvailableT{https://eldorado.uni-dortmund.de/handle/2003/20098}{http://hdl.handle.net/2003/20098}{2007-08-17}",
- }
Genetic Programming entries for
Markus Brameier
Citations