GitHub - bkovitz/acclivation: Code for "Acclivation of Virtual Fitness Landscapes" (ALIFE, 2019) by Kovitz, Bender, and Poffald

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Code for "Acclivation of Virtual Fitness Landscapes" (ALIFE, 2019) by Kovitz, Bender, and Poffald

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Name		Name	Last commit message	Last commit date
Latest commit History 218 Commits
ALIFE2019_latex_example		ALIFE2019_latex_example
good_xy_3-10-19		good_xy_3-10-19
old		old
paper/ALIFE2018_latex_example		paper/ALIFE2018_latex_example
sds-master		sds-master
.gitignore		.gitignore
LEARNED		LEARNED
Makefile		Makefile
Makefile.old		Makefile.old
README		README
TODO		TODO
acclivation.bib		acclivation.bib
acclivation.tex		acclivation.tex
add_param_set.py		add_param_set.py
alifeconf.sty		alifeconf.sty
analyze.py		analyze.py
coordset.c		coordset.c
coordset.h		coordset.h
example_organism.dot		example_organism.dot
okbumps		okbumps
out.nice1		out.nice1
out.nice2		out.nice2
out.nice3		out.nice3
out.nice4		out.nice4
out.ok1		out.ok1
plot-all		plot-all
plot_fitness.py		plot_fitness.py
plot_xyz.py		plot_xyz.py
ratio.dot		ratio.dot
refs		refs
run.py		run.py
sa.c		sa.c
sa.i		sa.i
sds.c		sds.c
sds.h		sds.h
sdsalloc.h		sdsalloc.h
see-graph		see-graph
setup_sa.py		setup_sa.py
show.py		show.py
stat.r		stat.r
yxline1-phfunc.eps		yxline1-phfunc.eps
yxline1-phrange.eps		yxline1-phrange.eps
yxline1-vfunc.eps		yxline1-vfunc.eps
yxline1.dot		yxline1.dot
yxline2-phfunc.eps		yxline2-phfunc.eps
yxline2-phrange.eps		yxline2-phrange.eps
yxline2-vfunc.eps		yxline2-vfunc.eps
yxline2.dot		yxline2.dot

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A Brief History -or- How All These Files Got In This Repository
---------------------------------------------------------------

In 2017, Ben Kovitz wrote some spreading-activation code in Clojure and
tried running an evolutionary simulation of knobs+graph organisms
(where knobs provide initial values to propagate by spreading activation
through the graph to determine a phenotype at some designated nodes in
the graph). It produced some visually spectacular acclivated virtual fitness
functions with "buttes", but it wasn't clear what the result was.

In 2018, Ben Kovitz and Marcela Poffald ran a bunch of experiments with
varying parameters on the spreading-activation algorithm, and some
"hill-climber" algorithms to try to measure how much acclivation occurs
and under what conditions. Experiments took all night, and acclivation
seemed to occur unpredictably. We still had to look at plots of the
virtual fitness functions to see if acclivation had occurred. Under
some parameters, it occurred seldom; tiny changes to the parameters would
make it occur rarely, and it wasn't at all clear why.

Dave Bender and Ben Kovitz rewrote the whole thing in C with some Python
support to make it easier to see plots of the various functions. The
simulations ran in seconds rather than hours, but it still wasn't clear
what makes acclivation likely vs. unlikely. We added more parameters and
tried more experiments but we did not get predictable results. Even under
more-favorable parameter settings, acclivation did not as often as we though
it should, given the simple idea for why it should work--and our old
observations of runs with now-forgotten parameter settings where acclivation
happened on almost every run.

In 2019, we tried again, inspired by a suggestion from Etienne Barnard to
try feed-forward (as opposed to spreading-activation) networks and to
allow larger populations. The feed-forward networks performed even worse,
but the new experiments led us to figure out that only a narrow range of
the S constant in the transfer function (see the ALIFE paper) works, and
why: only then do cyclic compositions of the transfer function create a highly
tunable set of ranges of expansion and contraction of the global fitness
function. The Clojure code in 2017 happened to have the S constant in this
range. It had been chosen for an unrelated spreading-activation experiment
in order to put attractors at -0.5 and +0.5.