Robust engineering design of electronic circuits with active components using genetic programming and bond Graphs
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- @InCollection{Peng:2007:GPTP,
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author = "Xiangdong Peng and Erik D. Goodman and
Ronald C. Rosenberg",
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title = "Robust engineering design of electronic circuits with
active components using genetic programming and bond
Graphs",
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booktitle = "Genetic Programming Theory and Practice {V}",
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year = "2007",
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editor = "Rick L. Riolo and Terence Soule and Bill Worzel",
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series = "Genetic and Evolutionary Computation",
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chapter = "11",
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pages = "187--202",
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address = "Ann Arbor",
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month = "17-19" # may,
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publisher = "Springer",
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keywords = "genetic algorithms, genetic programming",
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isbn13 = "978-0-387-76308-8",
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DOI = "doi:10.1007/978-0-387-76308-8_11",
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size = "15 pages",
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abstract = "Genetic programming has been used by Koza and many
others to design electrical, mechanical, and
mechatronic systems, including systems with both active
and passive components. This work has often required
large population sizes (on the order of ten thousand)
and millions of design evaluations to allow evolution
of both the topology and parameters of interesting
systems. For several years, the authors have studied
the evolution of multi-domain engineering systems
represented as bond graphs, a form that provides a
unified representation of mechanical, electrical,
hydraulic, pneumatic, thermal, and other systems in a
unified representation. Using this approach, called the
Genetic Programming/Bond Graph (GPBG) approach, they
have tried to evolve systems with perhaps tens of
components, but looking at only 100,000 or fewer design
candidates. The GPBG system uses much smaller
population sizes, but seeks to maintain diverse search
by using sustained evolutionary search processes such
as the Hierarchical Fair Competition principle and its
derivatives. It uses stochastic setting of parameter
values (resistances, capacitances, etc.) as a means of
evolving more robust designs. However, in past work,
the GPBG system was able to model and simulate only
passive components and simple (voltage or current, in
the case of electrical systems) sources, which severely
restricted the domain of problems it could address.
Thus, this paper reports the first steps in enhancing
the system to include active components. To date, only
three models of a transistor and one model of an
operational amplifier (op amp) are analysed and
implemented as two-port bond graph components. The
analysis method and design strategy can be easily
extended to other models or other active components or
even multi-port components. This chapter describes
design of an active analog low-pass filter with
fifth-order Bessel characteristics. A passive filter
with the same characteristics is also evolved with
GPBG. Then the best designs emerging from each of these
two procedures are compared. [The runs reported here
are intended only to document that the analysis tools
are working, and to begin study of the effects of
stochasticity, but not to determine the power of the
design procedure. The initial runs did not use HFC or
structure fitness sharing, which will be included as
soon as possible. Suitable problems will be tackled,
and results with suitable numbers of replicates to
allow drawing of statistically valid conclusions will
be reported in this paper, to determine whether
interesting circuits can be evolved more efficiently in
this framework than using other GP approaches.]",
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notes = "part of \cite{Riolo:2007:GPTP} published 2008",
- }
Genetic Programming entries for
Xiangdong Peng
Erik Goodman
Ronald C Rosenberg
Citations