more graphs for evo1d

2017-10-01 20:06:41 +02:00 · 2017-10-01 20:06:41 +02:00 · 3ce0a99591
commit 3ce0a99591
parent c0399a9499
25 changed files with 918 additions and 90 deletions
--- a/arbeit/bibma.bib
+++ b/arbeit/bibma.bib
@ -50,3 +50,28 @@
 publisher = {Springer-Verlag},
 address = {Berlin, Heidelberg},
 } 
@book{golub2012matrix,
  title={Matrix computations},
  author={Golub, Gene H and Van Loan, Charles F},
  volume={3},
  year={2012},
  publisher={JHU Press}
 }
@article{weise2012evolutionary,
  title={Evolutionary Optimization: Pitfalls and Booby Traps},
  author={Weise, Thomas and Chiong, Raymond and Tang, Ke},
  journal={J. Comput. Sci. \& Technol},
  volume={27},
  number={5},
  year={2012},
  url={http://jcst.ict.ac.cn:8080/jcst/EN/article/downloadArticleFile.do?attachType=PDF\&id=9543}
 }
@inproceedings{thorhauer2014locality,
  title={On the locality of standard search operators in grammatical evolution},
  author={Thorhauer, Ann and Rothlauf, Franz},
  booktitle={International Conference on Parallel Problem Solving from Nature},
  pages={465--475},
  year={2014},
  organization={Springer},
  url={https://www.lri.fr/~hansen/proceedings/2014/PPSN/papers/8672/86720465.pdf}
 }
--- a/arbeit/files/erklaerung.aux
+++ b/arbeit/files/erklaerung.aux
@ -22,7 +22,7 @@
 \setcounter{ContinuedFloat}{0}
 \setcounter{float@type}{16}
 \setcounter{lstnumber}{1}
-\setcounter{NAT@ctr}{5}
+\setcounter{NAT@ctr}{8}
 \setcounter{AM@survey}{0}
 \setcounter{r@tfl@t}{0}
 \setcounter{subfigure}{0}
--- a/arbeit/ma.md
+++ b/arbeit/ma.md
@ -4,14 +4,16 @@ fontsize: 11pt
 \chapter*{How to read this Thesis}
-As a guide through the nomenclature used in the formulas we prepend this chapter.
+As a guide through the nomenclature used in the formulas we prepend this
 chapter.
 Unless otherwise noted the following holds:
 - lowercase letters $x,y,z$  
  refer to real variables and represent a point in 3D-Space.
 - lowercase letters $u,v,w$  
-  refer to real variables between $0$ and $1$ used as coefficients in a 3D B-Spline grid.
+  refer to real variables between $0$ and $1$ used as coefficients in a 3D
  B-Spline grid.
 - other lowercase letters  
  refer to other scalar (real) variables.
 - lowercase **bold** letters (e.g. $\vec{x},\vec{y}$)  
@ -21,12 +23,13 @@ Unless otherwise noted the following holds:
 # Introduction
-In this Master Thesis we try to extend a previously proposed concept of predicting
+In this Master Thesis we try to extend a previously proposed concept of
-the evolvability of \acf{FFD} given a Deformation-Matrix\cite{anrichterEvol}.
+predicting the evolvability of \acf{FFD} given a
-In the original publication the author used random sampled points weighted with
+Deformation-Matrix\cite{anrichterEvol}. In the original publication the author
-\acf{RBF} to deform the mesh and defined three different criteria that can be
+used random sampled points weighted with \acf{RBF} to deform the mesh and
-calculated prior to using an evolutional optimisation algorithm to asses the
+defined three different criteria that can be calculated prior to using an
-quality and potential of such optimisation.
+evolutional optimization algorithm to asses the quality and potential of such
 optimization.
 We will replicate the same setup on the same meshes but use \acf{FFD} instead of
 \acf{RBF} to create a deformation and evaluate if the evolution-criteria still
@ -35,12 +38,14 @@ work as a predictor given the different deformation scheme.
 ## What is \acf{FFD}?
 First of all we have to establish how a \ac{FFD} works and why this is a good
-tool for deforming meshes in the first place. For simplicity we only summarize the
+tool for deforming meshes in the first place. For simplicity we only summarize
-1D-case from \cite{spitzmuller1996bezier} here and go into the extension to the 3D case in chapter \ref{3dffd}.
+the 1D-case from \cite{spitzmuller1996bezier} here and go into the extension to
 the 3D case in chapter \ref{3dffd}.
 Given an arbitrary number of points $p_i$ alongside a line, we map a scalar
 value $\tau_i \in [0,1[$ to each point with $\tau_i < \tau_{i+1} \forall i$.
-Given a degree of the target polynomial $d$ we define the curve $N_{i,d,\tau_i}(u)$ as follows:
+Given a degree of the target polynomial $d$ we define the curve
 $N_{i,d,\tau_i}(u)$ as follows:
 \begin{equation} \label{eqn:ffd1d1}
 N_{i,0,\tau}(u) = \begin{cases} 1, & u \in [\tau_i, \tau_{i+1}[ \\ 0, & \mbox{otherwise} \end{cases}
@ -52,12 +57,17 @@ and
 N_{i,d,\tau}(u) = \frac{u-\tau_i}{\tau_{i+d}} N_{i,d-1,\tau}(u) + \frac{\tau_{i+d+1} - u}{\tau_{i+d+1}-\tau_{i+1}} N_{i+1,d-1,\tau}(u)
 \end{equation}
-If we now multiply every $p_i$ with the corresponding $N_{i,d,\tau_i}(u)$ we get the contribution of each
+If we now multiply every $p_i$ with the corresponding $N_{i,d,\tau_i}(u)$ we get
-point $p_i$ to the final curve-point parameterized only by $u \in [0,1[$.
+the contribution of each point $p_i$ to the final curve-point parameterized only
-As can be seen from \eqref{eqn:ffd1d2} we only access points $[i..i+d]$ for any given $i$^[one more for each recursive step.], which
+by $u \in [0,1[$.  As can be seen from \eqref{eqn:ffd1d2} we only access points
-gives us, in combination with choosing $p_i$ and $\tau_i$ in order, only a local interference of $d+1$ points.
+$[i..i+d]$ for any given $i$^[one more for each recursive step.], which gives
 us, in combination with choosing $p_i$ and $\tau_i$ in order, only a local
 interference of $d+1$ points.
-We can even derive this equation straightforward for an arbitrary $N$^[*Warning:* in the case of $d=1$ the recursion-formula yields a $0$ denominator, but $N$ is also $0$. The right solution for this case is a derivative of $0$]:
+We can even derive this equation straightforward for an arbitrary
 $N$^[*Warning:* in the case of $d=1$ the recursion-formula yields a $0$
 denominator, but $N$ is also $0$. The right solution for this case is a
 derivative of $0$]:
 $$\frac{\partial}{\partial u} N_{i,d,r}(u) = \frac{d}{\tau_{i+d} - \tau_i} N_{i,d-1,\tau}(u) - \frac{d}{\tau_{i+d+1} - \tau_{i+1}} N_{i+1,d-1,\tau}(u)$$
@ -65,30 +75,42 @@ For a B-Spline
 $$s(u) = \sum_{i} N_{i,d,\tau_i}(u) p_i$$
 these derivations yield $\frac{\partial^d}{\partial u} s(u) = 0$.
-Another interesting property of these recursive polynomials is that they are continuous (given $d \ge 1$) as every $p_i$ gets
+Another interesting property of these recursive polynomials is that they are
-blended in linearly between $\tau_i$ and $\tau_{i+d}$ and out linearly between $\tau_{i+1}$ and $\tau_{i+d+1}$
+continuous (given $d \ge 1$) as every $p_i$ gets blended in linearly between
-as can bee seen from the two coefficients in every step of the recursion.
+$\tau_i$ and $\tau_{i+d}$ and out linearly between $\tau_{i+1}$ and
 $\tau_{i+d+1}$ as can bee seen from the two coefficients in every step of the
 recursion.
 ### Why is \ac{FFD} a good deformation function?
-The usage of \ac{FFD} as a tool for manipulating follows directly from the properties of the polynomials and the correspondence to
+The usage of \ac{FFD} as a tool for manipulating follows directly from the
-the control points.
+properties of the polynomials and the correspondence to the control points.
-Having only a few control points gives the user a nicer high-level-interface, as she only needs to move these points and the
+Having only a few control points gives the user a nicer high-level-interface, as
-model follows in an intuitive manner. The deformation is smooth as the underlying polygon is smooth as well and affects as many
+she only needs to move these points and the model follows in an intuitive
-vertices of the model as needed. Moreover the changes are always local so one risks not any change that a user cannot immediately see.
+manner. The deformation is smooth as the underlying polygon is smooth as well
 and affects as many vertices of the model as needed. Moreover the changes are
 always local so one risks not any change that a user cannot immediately see.
-But there are also disadvantages of this approach. The user loses the ability to directly influence vertices and even seemingly simple tasks as
+But there are also disadvantages of this approach. The user loses the ability to
-creating a plateau can be difficult to achieve\cite[chapter~3.2]{hsu1991dmffd}\cite{hsu1992direct}.
+directly influence vertices and even seemingly simple tasks as creating a
 plateau can be difficult to
 achieve\cite[chapter~3.2]{hsu1991dmffd}\cite{hsu1992direct}.
-This disadvantages led to the formulation of \acf{DM-FFD}\cite[chapter~3.3]{hsu1991dmffd} in which the user directly interacts with the surface-mesh.
+This disadvantages led to the formulation of
-All interactions will be applied proportionally to the control-points that make up the parametrization of the interaction-point
+\acf{DM-FFD}\cite[chapter~3.3]{hsu1991dmffd} in which the user directly
-itself yielding a smooth deformation of the surface *at* the surface without seemingly arbitrary scattered control-points.
+interacts with the surface-mesh.  All interactions will be applied
-Moreover this increases the efficiency of an evolutionary optimization\cite{Menzel2006}, which we will use later on.
+proportionally to the control-points that make up the parametrization of the
 interaction-point itself yielding a smooth deformation of the surface *at* the
 surface without seemingly arbitrary scattered control-points.  Moreover this
 increases the efficiency of an evolutionary optimization\cite{Menzel2006}, which
 we will use later on.
-But this approach also has downsides as can be seen in \cite[figure~7]{hsu1991dmffd}\todo{figure hier einfügen?}, as the tessellation of
+But this approach also has downsides as can be seen in
-the invisible grid has a major impact on the deformation itself.
+\cite[figure~7]{hsu1991dmffd}\todo{figure hier einfügen?}, as the tessellation
 of the invisible grid has a major impact on the deformation itself.
-All in all \ac{FFD} and \ac{DM-FFD} are still good ways to deform a high-polygon mesh albeit the downsides.
+All in all \ac{FFD} and \ac{DM-FFD} are still good ways to deform a high-polygon
 mesh albeit the downsides.
 ## What is evolutional optimization?
@ -96,26 +118,83 @@ All in all \ac{FFD} and \ac{DM-FFD} are still good ways to deform a high-polygon
 ## Wieso ist evo-Opt so cool?
-The main advantage of evolutional algorithms is the ability to find optima of general functions just with the help of a given
+The main advantage of evolutional algorithms is the ability to find optima of
-error-function (or fitness-function in this domain). This avoids the general pitfalls of gradient-based procedures, which often
+general functions just with the help of a given error-function (or
-target the same error-function as an evolutional algorithm, but can get stuck in local optima.
+fitness-function in this domain). This avoids the general pitfalls of
 gradient-based procedures, which often target the same error-function as an
 evolutional algorithm, but can get stuck in local optima.
-This is mostly due to the fact that a gradient-based procedure has only one point of observation from where it evaluates the next
+This is mostly due to the fact that a gradient-based procedure has only one
-steps, whereas an evolutional strategy starts with a population of guessed solutions. Because an evolutional strategy modifies
+point of observation from where it evaluates the next steps, whereas an
-the solution randomly, keeps the best solutions and purges the worst, it can also target multiple different hypothesis at the same time
+evolutional strategy starts with a population of guessed solutions. Because an
-where the local optima die out in the face of other, better candidates.
+evolutional strategy modifies the solution randomly, keeps the best solutions
 and purges the worst, it can also target multiple different hypothesis at the
 same time where the local optima die out in the face of other, better
 candidates.
-If an analytic best solution exists (i.e. because the error-function is convex) an evolutional algorithm is not the right choice. Although
+If an analytic best solution exists (i.e. because the error-function is convex)
-both converge to the same solution, the analytic one is usually faster. But in reality many problems have no analytic solution, because
+an evolutional algorithm is not the right choice. Although both converge to the
-the problem is not convex. Here evolutional optimization has one more advantage as you get bad solutions fast, which refine over time.
+same solution, the analytic one is usually faster. But in reality many problems
 have no analytic solution, because the problem is not convex. Here evolutional
 optimization has one more advantage as you get bad solutions fast, which refine
 over time.
 ## Criteria for the evolvability of linear deformations
 ### Variability
-## Evolvierbarkeitskriterien
+In \cite{anrichterEvol} variability is defined as
 $$V(\vec{U}) := \frac{\textrm{rank}(\vec{U})}{n},$$
 whereby $\vec{U}$ is the $m \times n$ deformation-Matrix used to map the $m$
 control points onto the $n$ vertices.
- Konditionszahl etc.
+Given $n = m$, an identical number of control-points and vertices, this
 quotient will be $=1$ if all control points are independent of each other and
 the solution is to trivially move every control-point onto a target-point.
-# Hauptteil
+In praxis the value of $V(\vec{U})$ is typically $\ll 1$, because as
 there are only few control-points for many vertices, so $m \ll n$.
 Additionally in our setup we connect neighbouring control-points in a grid so
 each control point is not independent, but typically depends on $4^d$
 control-points for an $d$-dimensional control mesh.
 ### Regularity
 Regularity is defined\cite{anrichterEvol} as
 $$R(\vec{U}) := \frac{1}{\kappa(\vec{U})} = \frac{\sigma_{min}}{\sigma_{max}}$$
 where $\sigma_{min}$ and $\sigma_{max}$ are the smallest and greatest right singular
 value of the deformation-matrix $\vec{U}$.
 As we deform the given Object only based on the parameters as $\vec{p} \mapsto
 f(\vec{x} + \vec{U}\vec{p})$ this makes sure that $\|\vec{Up}\| \propto
 \|\vec{p}\|$ when $\kappa(\vec{U}) \approx 1$. The inversion of $\kappa(\vec{U})$
 is only performed to map the criterion-range to $[0..1]$, whereas $1$ is the
 optimal value and $0$ is the worst value.
 This criterion should be characteristic for numeric stability on the on
 hand\cite[chapter 2.7]{golub2012matrix} and for convergence speed of evolutional
 algorithms on the other hand\cite{anrichterEvol} as it is tied to the notion of
 locality\cite{weise2012evolutionary,thorhauer2014locality}.
 ### Improvement Potential
 In contrast to the general nature of variability and regularity, which are
 agnostic of the fitness-function at hand the third criterion should reflect a
 notion of potential.
 As during optimization some kind of gradient $g$ is available to suggest a
 direction worth pursuing we use this to guess how much change can be achieved in
 the given direction.
 The definition for an improvement potential $P$ is\cite{anrichterEvol}:
 $$
 P(\vec{U}) := 1 - \|(\vec{1} - \vec{UU}^+)\vec(G)\|^2_F
 $$
 given some approximate $n \times d$ fitness-gradient $\vec{G}$, normalized to
 $\|\vec{G}\|_F = 1$, whereby $\|\cdot\|_F$ denotes the Frobenius-Norm.
 # Implementation of \acf{FFD}
 ## Was ist FFD?
 \label{3dffd}
@ -124,41 +203,43 @@ the problem is not convex. Here evolutional optimization has one more advantage
 - Wieso Newton-Optimierung?
  - Was folgt daraus?
-## Szenarien vorstellen
+## Test Scenario: 1D Function Approximation
-### 1D
+### Optimierungszenario
 #### Optimierungszenario
 - Ebene -> Template-Fit
-#### Matching in 1D
+### Matching in 1D
 - Trivial
-#### Besonderheiten der Auswertung
+### Besonderheiten der Auswertung
 - Analytische Lösung einzig beste
  - Ergebnis auch bei Rauschen konstant?
  - normierter 1-Vektor auf den Gradienten addieren
    - Kegel entsteht
-### 3D
+## Test Scenario: 3D Function Approximation
-#### Optimierungsszenario
+### Optimierungsszenario
 - Ball zu Mario
-#### Matching in 3D
+### Matching in 3D
 - alternierende Optimierung
-#### Besonderheiten der Optimierung
+### Besonderheiten der Optimierung
 - Analytische Lösung nur bis zur Optimierung der ersten Punkte gültig
 - Kriterien trotzdem gut
-# Evaluation
+# Evaluation of Scenarios
 ## Results of 1D Function Approximation
 ## Spearman/Pearson-Metriken
@ -166,7 +247,7 @@ the problem is not convex. Here evolutional optimization has one more advantage
 - Wieso sollte uns das interessieren?
 - Wieso reicht Monotonie?
 - Haben wir das gezeigt?
- Stastik, Bilder, blah!
+- Statistik, Bilder, blah!
 # Schluss
--- a/arbeit/ma.pdf
+++ b/arbeit/ma.pdf
--- a/arbeit/ma.tex
+++ b/arbeit/ma.tex
@ -151,8 +151,8 @@ predicting the evolvability of \acf{FFD} given a
 Deformation-Matrix\cite{anrichterEvol}. In the original publication the
 author used random sampled points weighted with \acf{RBF} to deform the
 mesh and defined three different criteria that can be calculated prior
-to using an evolutional optimisation algorithm to asses the quality and
+to using an evolutional optimization algorithm to asses the quality and
-potential of such optimisation.
+potential of such optimization.
 We will replicate the same setup on the same meshes but use \acf{FFD}
 instead of \acf{RBF} to create a deformation and evaluate if the
@ -265,13 +265,64 @@ in reality many problems have no analytic solution, because the problem
 is not convex. Here evolutional optimization has one more advantage as
 you get bad solutions fast, which refine over time.
-\section{Evolvierbarkeitskriterien}\label{evolvierbarkeitskriterien}
+\section{Criteria for the evolvability of linear
 deformations}\label{criteria-for-the-evolvability-of-linear-deformations}
-\begin{itemize}
+\subsection{Variability}\label{variability}
-\tightlist
+
-\item
+In \cite{anrichterEvol} variability is defined as
-  Konditionszahl etc.
+\[V(\vec{U}) := \frac{\textrm{rank}(\vec{U})}{n},\] whereby \(\vec{U}\)
-\end{itemize}
+is the \(m \times n\) deformation-Matrix used to map the \(m\) control
 points onto the \(n\) vertices.
 Given \(n = m\), an identical number of control-points and vertices,
 this quotient will be \(=1\) if all control points are independent of
 each other and the solution is to trivially move every control-point
 onto a target-point.
 In praxis the value of \(V(\vec{U})\) is typically \(\ll 1\), because as
 there are only few control-points for many vertices, so \(m \ll n\).
 Additionally in our setup we connect neighbouring control-points in a
 grid so each control point is not independent, but typically depends on
 \(4^d\) control-points for an \(d\)-dimensional control mesh.
 \subsection{Regularity}\label{regularity}
 Regularity is defined\cite{anrichterEvol} as
 \[R(\vec{U}) := \frac{1}{\kappa(\vec{U})} = \frac{\sigma_{min}}{\sigma_{max}}\]
 where \(\sigma_{min}\) and \(\sigma_{max}\) are the smallest and
 greatest right singular value of the deformation-matrix \(\vec{U}\).
 As we deform the given Object only based on the parameters as
 \(\vec{p} \mapsto f(\vec{x} + \vec{U}\vec{p})\) this makes sure that
 \(\|\vec{Up}\| \propto \|\vec{p}\|\) when \(\kappa(\vec{U}) \approx 1\).
 The inversion of \(\kappa(\vec{U})\) is only performed to map the
 criterion-range to \([0..1]\), whereas \(1\) is the optimal value and
 \(0\) is the worst value.
 This criterion should be characteristic for numeric stability on the on
 hand\cite[chapter 2.7]{golub2012matrix} and for convergence speed of
 evolutional algorithms on the other hand\cite{anrichterEvol} as it is
 tied to the notion of
 locality\cite{weise2012evolutionary,thorhauer2014locality}.
 \subsection{Improvement Potential}\label{improvement-potential}
 In contrast to the general nature of variability and regularity, which
 are agnostic of the fitness-function at hand the third criterion should
 reflect a notion of potential.
 As during optimization some kind of gradient \(g\) is available to
 suggest a direction worth pursuing we use this to guess how much change
 can be achieved in the given direction.
 The definition for an improvement potential \(P\)
 is\cite{anrichterEvol}: \[
 P(\vec{U}) := 1 - \|(\vec{1} - \vec{UU}^+)\vec(G)\|^2_F
 \] given some approximate \(n \times d\) fitness-gradient \(\vec{G}\),
 normalized to \(\|\vec{G}\|_F = 1\), whereby \(\|\cdot\|_F\) denotes the
 Frobenius-Norm.
 \chapter{Hauptteil}\label{hauptteil}
@ -372,7 +423,7 @@ Optimierung}\label{besonderheiten-der-optimierung}
 \item
  Haben wir das gezeigt?
 \item
-  Stastik, Bilder, blah!
+  Statistik, Bilder, blah!
 \end{itemize}
 \chapter{Schluss}\label{schluss}
--- a/arbeit/settings/commands.tex
+++ b/arbeit/settings/commands.tex
@ -87,13 +87,13 @@
 \renewcommand\lq{\text{\textgravedbl}\!\!}\renewcommand\rq{\!\!\text{\textacutedbl}}
 % ##### tables #####
-\newcommand\rl[1]{\multicolumn{1}{r|}{#1}}			% item|
+% \newcommand\rl[1]{\multicolumn{1}{r|}{#1}}			% item|
-\renewcommand\ll[1]{\multicolumn{1}{|r}{#1}}		% |item
+% \renewcommand\ll[1]{\multicolumn{1}{|r}{#1}}		% |item
-% \newcommand\cc[1]{\multicolumn{1}{|c|}{#1}} 		% |item|
+% % \newcommand\cc[1]{\multicolumn{1}{|c|}{#1}} 		% |item|
-\newcommand\lc[2]{\multicolumn{#1}{|c|}{#2}}		%
+% \newcommand\lc[2]{\multicolumn{#1}{|c|}{#2}}		%
-\newcommand\cc[1]{\multicolumn{1}{c}{#1}}
+% \newcommand\cc[1]{\multicolumn{1}{c}{#1}}
-% \renewcommand{\arraystretch}{1.2} % Tabellenzeilen ein bischen h?her machen.
+% % \renewcommand{\arraystretch}{1.2} % Tabellenzeilen ein bischen h?her machen.
-\newcommand\m[2]{\multirow{#1}{*}{$#2$}}
+% \newcommand\m[2]{\multirow{#1}{*}{$#2$}}
 % ##### Text symbole #####
 % \newcommand\subdot[1]{\lower0.5em\hbox{$\stackrel{\displaystyle #1}{.}$}}
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one.gnuplot.fit.log
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one.gnuplot.fit.log
@ -1,7 +1,7 @@
 *******************************************************************************
-Wed Aug 30 22:31:49 2017
+Sun Oct  1 19:59:33 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 2:5
@ -47,7 +47,7 @@ b              -0.996  1.000
 *******************************************************************************
-Wed Aug 30 22:31:49 2017
+Sun Oct  1 19:59:33 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:5
@ -93,7 +93,7 @@ bb             -1.000  1.000
 *******************************************************************************
-Wed Aug 30 22:31:49 2017
+Sun Oct  1 19:59:33 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:6
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one.gnuplot.script
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one.gnuplot.script
@ -2,13 +2,19 @@ set datafile separator ","
 f(x)=a*x+b
 fit f(x) "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 2:5 via a,b
 set terminal png
 set xlabel 'regularity'
 set ylabel 'steps'
 set output "20170830-evolution1D_5x5_100Times-added_one_regularity-vs-steps.png"
-plot "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 2:5 title "regularity vs. steps", f(x) lc rgb "black"
+plot "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 2:5 title "data", f(x) title "lin. fit" lc rgb "black"
 g(x)=aa*x+bb
 fit g(x) "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:5 via aa,bb
 set xlabel 'improvement potential'
 set ylabel 'steps'
 set output "20170830-evolution1D_5x5_100Times-added_one_improvement-vs-steps.png"
-plot "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:5 title "improvement potential vs. steps", g(x) lc rgb "black"
+plot "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:5 title "data", g(x) title "lin. fit" lc rgb "black"
 h(x)=aaa*x+bbb
 fit h(x) "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:6 via aaa,bbb
 set xlabel 'improvement potential'
 set ylabel 'evolution error'
 set output "20170830-evolution1D_5x5_100Times-added_one_improvement-vs-evo-error.png"
-plot "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:6 title "improvement potential vs. evolution error", h(x) lc rgb "black"
+plot "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:6 title "data", h(x) title "lin. fit" lc rgb "black"
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one_improvement-vs-evo-error.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one_improvement-vs-evo-error.png
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one_improvement-vs-steps.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one_improvement-vs-steps.png
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one_regularity-vs-steps.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-added_one_regularity-vs-steps.png
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all.csv
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all.csv
@ -0,0 +1,201 @@
 "Least squares",regularity,variability,improvement,steps,"Evolution error",sigma
 183.763,0.0179571,0.00111111,0.938632,228,192.44,0.032644
 229.099,0.0189281,0.00111111,0.923492,96,240.171,0.0562716
 238.479,0.0215758,0.00111111,0.920359,195,249.883,0.0272032
 188.152,0.0144312,0.00111111,0.937166,256,197.529,0.0244736
 191.586,0.0207835,0.00111111,0.936019,156,201.143,0.0235659
 202.916,0.0168021,0.00111111,0.932236,220,212.978,0.0318143
 178.439,0.0180162,0.00111111,0.94041,259,187.236,0.0269287
 229.734,0.0238245,0.00111111,0.92328,203,241.13,0.0281426
 211.994,0.0192363,0.00111111,0.929204,211,222.511,0.0152364
 245.717,0.0185166,0.00111111,0.917942,154,256.592,0.0379309
 225.543,0.0204032,0.00111111,0.92468,160,236.693,0.0243299
 211.533,0.0207268,0.00111111,0.929358,135,221.694,0.0377055
 213.806,0.022426,0.00111111,0.928599,188,224.469,0.0237864
 223.483,0.0172601,0.00111111,0.925368,203,234.382,0.0196412
 231.924,0.0177059,0.00111111,0.922549,209,243.433,0.0259235
 184.824,0.0162623,0.00111111,0.938278,242,194.032,0.0222468
 223.766,0.0179083,0.00111111,0.925273,207,234.567,0.0301655
 203.27,0.0161445,0.00111111,0.932118,220,213.401,0.0273719
 193.158,0.0166659,0.00111111,0.935494,221,201.428,0.0414548
 197.851,0.0185201,0.00111111,0.933927,195,207.224,0.0362339
 214.041,0.0178594,0.00111111,0.928521,139,224.585,0.0340444
 211.533,0.018782,0.00111111,0.929358,132,221.895,0.0369246
 185.356,0.0195083,0.00111111,0.9381,222,194.499,0.0184425
 198.81,0.0201802,0.00111111,0.933607,242,208.589,0.0259606
 205.265,0.0202697,0.00111111,0.931451,184,215.456,0.0190532
 222.952,0.019699,0.00111111,0.925545,178,234.028,0.0261726
 205.276,0.0193633,0.00111111,0.931448,191,214.716,0.02818
 230.047,0.0214453,0.00111111,0.923175,216,241.431,0.0234518
 196.924,0.0190251,0.00111111,0.934237,183,206.599,0.0212354
 195.184,0.0181113,0.00111111,0.934818,178,204.769,0.0299481
 194.787,0.018323,0.00111111,0.934951,212,204.23,0.0294953
 212.533,0.0182128,0.00111111,0.929024,231,222.938,0.0412254
 176.623,0.0158336,0.00111111,0.941017,209,185.355,0.0266792
 209.136,0.0204612,0.00111111,0.930159,91,218.429,0.0579325
 209.848,0.0201986,0.00111111,0.929921,163,219.886,0.0336554
 209.515,0.0191636,0.00111111,0.930032,185,219.696,0.0286176
 193.943,0.0178079,0.00111111,0.935233,199,203.581,0.0232988
 216.239,0.0212003,0.00111111,0.927787,151,226.759,0.0189421
 211.37,0.0162232,0.00111111,0.929413,173,221.819,0.0171682
 224.988,0.0196037,0.00111111,0.924865,112,236.226,0.0602406
 207.221,0.0185908,0.00111111,0.930798,157,217.553,0.0314001
 203.513,0.0172686,0.00111111,0.932037,188,213.564,0.0328506
 186.642,0.0195431,0.00111111,0.937671,178,195.759,0.0419734
 236.265,0.0204047,0.00111111,0.921099,106,247.931,0.0409088
 222.669,0.0231925,0.00111111,0.925639,162,233.713,0.0215862
 223.48,0.0208053,0.00111111,0.925369,190,234.013,0.0261078
 213.098,0.0182925,0.00111111,0.928835,227,223.628,0.0354102
 185.847,0.0198307,0.00111111,0.937936,217,194.983,0.0198853
 215.818,0.0211463,0.00111111,0.927927,212,226.437,0.0327274
 203.914,0.0228368,0.00111111,0.931903,219,214.086,0.0166239
 177.639,0.0183023,0.00111111,0.940677,243,186.419,0.0388416
 187.065,0.0182927,0.00111111,0.937529,217,196.416,0.0185577
 224.069,0.0206082,0.00111111,0.925172,240,235.058,0.0214527
 233.059,0.020766,0.00111111,0.922169,249,244.587,0.0304497
 243.252,0.0197131,0.00111111,0.918766,218,255.376,0.0210078
 216.096,0.018823,0.00111111,0.927834,240,226.808,0.0218857
 229.899,0.0235834,0.00111111,0.923225,185,241.372,0.0226563
 214.545,0.02158,0.00111111,0.928352,180,225.08,0.0281248
 201.315,0.0215738,0.00111111,0.932771,122,210.821,0.0306565
 196.866,0.0199231,0.00111111,0.934256,254,206.672,0.0171958
 191.811,0.0187791,0.00111111,0.935944,264,201.399,0.0284519
 234.589,0.0153778,0.00111111,0.921659,173,246.066,0.0288251
 241.822,0.0210075,0.00111111,0.919243,147,253.875,0.0448453
 247.389,0.020118,0.00111111,0.917384,180,259.741,0.0237541
 197.862,0.0191194,0.00111111,0.933924,258,207.655,0.0309044
 227.298,0.0193875,0.00111111,0.924094,189,238.654,0.0244366
 203.016,0.0194783,0.00111111,0.932203,345,213.147,0.0293344
 200.344,0.0181137,0.00111111,0.933095,211,210.34,0.0279667
 260.653,0.0211892,0.00111111,0.912955,159,273.684,0.0173598
 190.801,0.018724,0.00111111,0.936282,145,200.321,0.0244174
 219.31,0.0152034,0.00111111,0.926761,298,230.127,0.0304617
 201.013,0.0189705,0.00111111,0.932871,154,210.898,0.0368793
 214.751,0.0212631,0.00111111,0.928283,189,224.914,0.0281325
 199.042,0.0200792,0.00111111,0.93353,228,208.711,0.0294291
 222.258,0.0190311,0.00111111,0.925777,220,233.241,0.0218053
 193.965,0.0185556,0.00111111,0.935225,281,203.658,0.0236132
 216.305,0.0220209,0.00111111,0.927765,187,227.058,0.0289074
 209.518,0.0164836,0.00111111,0.930031,193,219.89,0.0252204
 202.805,0.0195855,0.00111111,0.932273,235,212.877,0.0518397
 205.584,0.0203958,0.00111111,0.931345,203,215.439,0.0362367
 181.975,0.0182167,0.00111111,0.939229,173,191.017,0.0257238
 161.995,0.0204489,0.00111111,0.945902,260,170.069,0.0166518
 194.688,0.0204944,0.00111111,0.934984,184,204.348,0.0314503
 185.811,0.0200401,0.00111111,0.937948,332,195.049,0.0270099
 197.624,0.020823,0.00111111,0.934003,281,207.186,0.0391989
 214.766,0.0218128,0.00111111,0.928278,157,225.229,0.0353567
 219.632,0.0173274,0.00111111,0.926653,160,230.466,0.036049
 202.581,0.0162571,0.00111111,0.932348,237,212.578,0.0297746
 181.621,0.0177214,0.00111111,0.939347,316,190.496,0.0259462
 250.268,0.0185787,0.00111111,0.916423,135,262.382,0.0245029
 205.717,0.0178907,0.00111111,0.931301,255,215.988,0.0274579
 197.391,0.0189724,0.00111111,0.934081,215,206.934,0.0376919
 238.981,0.0223217,0.00111111,0.920192,100,250.737,0.0435432
 196.091,0.01434,0.00111111,0.934515,190,205.827,0.0556249
 202.756,0.0184759,0.00111111,0.932289,271,212.891,0.0270203
 191.765,0.0184657,0.00111111,0.93596,193,201.034,0.0201355
 202.525,0.0186188,0.00111111,0.932366,239,212.53,0.0201397
 198.694,0.0176067,0.00111111,0.933646,278,208.545,0.0231376
 196.578,0.0184124,0.00111111,0.934353,226,206.327,0.0391784
 190.046,0.0198379,0.00111111,0.936534,133,199.413,0.0284771
 198.091,0.0185605,0.00111111,0.933847,245,207.886,0.0152523
 234.524,0.0192422,0.00111111,0.92168,203,245.873,0.0333896
 199.665,0.0169589,0.00111111,0.933322,236,209.253,0.0256795
 225.432,0.019794,0.00111111,0.924717,164,236.693,0.0303567
 226.331,0.0198218,0.00111111,0.924416,133,237.512,0.0326327
 207.081,0.0183173,0.00111111,0.930845,293,217.347,0.0173303
 197.215,0.0195282,0.00111111,0.93414,144,206.725,0.0274424
 207.985,0.018551,0.00111111,0.930543,167,218.216,0.0264904
 199.179,0.0192478,0.00111111,0.933484,230,208.831,0.0280096
 190.622,0.0185748,0.00111111,0.936342,146,199.805,0.040456
 186.169,0.0193022,0.00111111,0.937829,196,195.163,0.0339487
 184.072,0.0170487,0.00111111,0.938529,224,193.258,0.0325346
 173.247,0.0203667,0.00111111,0.942144,191,181.901,0.0186411
 174.505,0.0185505,0.00111111,0.941724,232,183.091,0.0391035
 204.996,0.019809,0.00111111,0.931541,126,215.233,0.0317816
 201.159,0.0177293,0.00111111,0.932823,231,210.992,0.033055
 215.57,0.0184879,0.00111111,0.92801,157,226.197,0.0248099
 220.4,0.0220813,0.00111111,0.926397,120,230.55,0.0266999
 192.669,0.0189865,0.00111111,0.935658,197,201.997,0.0273896
 217.249,0.0209109,0.00111111,0.927449,196,227.649,0.0314102
 183.442,0.0177993,0.00111111,0.938739,276,192.577,0.0290511
 211.058,0.0191396,0.00111111,0.929517,262,221.454,0.0258037
 225.405,0.0142923,0.00111111,0.924726,232,236.59,0.0554429
 214.129,0.0153926,0.00111111,0.928491,258,224.637,0.025707
 191.681,0.0159947,0.00111111,0.935988,221,201.263,0.0168213
 208.302,0.0168977,0.00111111,0.930437,267,218.685,0.0303307
 244.265,0.0186614,0.00111111,0.918427,240,256.401,0.014142
 217.424,0.0189707,0.00111111,0.927391,194,228.137,0.0234014
 193.974,0.0187277,0.00111111,0.935222,200,203.421,0.0313489
 217.843,0.0191009,0.00111111,0.927251,244,228.677,0.0186412
 228.126,0.0195362,0.00111111,0.923817,171,239.173,0.0237806
 194.236,0.0205534,0.00111111,0.935135,206,203.783,0.0222971
 231.826,0.017672,0.00111111,0.922582,126,243.217,0.0354461
 194.684,0.0180998,0.00111111,0.934985,149,204.188,0.0265668
 201.513,0.0176892,0.00111111,0.932705,232,211.535,0.0277219
 219.557,0.016394,0.00111111,0.926679,145,229.573,0.0466214
 215.208,0.0203045,0.00111111,0.928131,217,225.773,0.0198841
 224.784,0.0187965,0.00111111,0.924933,207,235.748,0.0249149
 198.752,0.0192186,0.00111111,0.933626,214,208.659,0.0198508
 210.374,0.0169978,0.00111111,0.929745,201,220.83,0.029392
 182.397,0.0156577,0.00111111,0.939088,271,191.357,0.0356415
 214.532,0.017907,0.00111111,0.928357,187,224.938,0.0315807
 206.254,0.0198955,0.00111111,0.931121,144,216.195,0.0261497
 208.845,0.019427,0.00111111,0.930256,302,218.868,0.0293849
 219.847,0.018273,0.00111111,0.926582,205,230.63,0.0222702
 178.072,0.0161684,0.00111111,0.940532,271,186.89,0.0224425
 208.094,0.0174596,0.00111111,0.930507,188,218.199,0.026439
 206.759,0.017792,0.00111111,0.930952,249,217.047,0.0196121
 213.588,0.0179354,0.00111111,0.928672,154,223.644,0.0261114
 203.691,0.0186109,0.00111111,0.931977,215,213.801,0.029634
 196.02,0.0164293,0.00111111,0.934539,286,205.631,0.0248201
 200.893,0.0206686,0.00111111,0.932911,218,210.824,0.0165101
 219.308,0.018868,0.00111111,0.926762,202,230.178,0.0193291
 246.019,0.0189353,0.00111111,0.917842,155,257.369,0.0271402
 231.847,0.0197966,0.00111111,0.922574,168,243.262,0.0289334
 218.91,0.0209849,0.00111111,0.926895,197,229.047,0.0299942
 211.126,0.0167501,0.00111111,0.929494,196,221.493,0.0286991
 169.535,0.0151348,0.00111111,0.943383,175,177.905,0.0337364
 230.113,0.0201869,0.00111111,0.923153,167,241.468,0.0344348
 231.924,0.0200713,0.00111111,0.922549,149,243.443,0.0257716
 223.016,0.0200786,0.00111111,0.925524,178,233.782,0.0402102
 195.674,0.014894,0.00111111,0.934654,268,205.347,0.0551882
 255.95,0.0195439,0.00111111,0.914525,148,268.384,0.0447607
 220.055,0.0198234,0.00111111,0.926512,236,230.853,0.0367555
 216.155,0.0189146,0.00111111,0.927815,129,226.312,0.0430726
 199.784,0.0187532,0.00111111,0.933282,199,209.55,0.0353292
 222.549,0.0203982,0.00111111,0.925679,178,233.426,0.0233115
 200.95,0.0183086,0.00111111,0.932893,256,210.991,0.016803
 209.249,0.016696,0.00111111,0.930121,269,219.415,0.02081
 249.03,0.0223912,0.00111111,0.916836,177,260.926,0.0294009
 219.09,0.019419,0.00111111,0.926835,218,229.786,0.0289335
 185.792,0.0169305,0.00111111,0.937954,291,194.888,0.0258978
 184.383,0.0208635,0.00111111,0.938425,256,193.57,0.0185135
 201.82,0.0183427,0.00111111,0.932602,236,211.086,0.0474114
 226.705,0.0196988,0.00111111,0.924292,255,237.989,0.0227452
 206.776,0.019382,0.00111111,0.930947,187,217.102,0.0280757
 185.74,0.0141851,0.00111111,0.937972,166,194.775,0.0321003
 232.792,0.0240912,0.00111111,0.922259,191,244.384,0.0176279
 201.838,0.0188448,0.00111111,0.932596,181,211.814,0.0297108
 202.159,0.0179769,0.00111111,0.932489,175,212.073,0.0239756
 178.922,0.018115,0.00111111,0.940249,259,187.619,0.0215103
 196.096,0.0172259,0.00111111,0.934514,220,205.625,0.030462
 200.913,0.0195059,0.00111111,0.932905,162,210.781,0.0383751
 182.439,0.020238,0.00111111,0.939074,172,191.55,0.0264845
 169.79,0.018196,0.00111111,0.943298,226,178.258,0.0148133
 185.191,0.0167884,0.00111111,0.938155,194,194.329,0.0261194
 202.268,0.0211018,0.00111111,0.932452,200,212.217,0.0301675
 191.444,0.0189881,0.00111111,0.936067,211,200.944,0.0234532
 216.792,0.0196005,0.00111111,0.927602,200,227.453,0.0212078
 252.534,0.0172473,0.00111111,0.915666,225,264.972,0.0178314
 193.043,0.0156078,0.00111111,0.935533,226,202.656,0.0411515
 192.167,0.0174455,0.00111111,0.935826,195,201.39,0.0254769
 225.725,0.0178959,0.00111111,0.924619,240,236.882,0.018903
 204.599,0.0213119,0.00111111,0.931674,171,214.712,0.0263085
 185.635,0.0163761,0.00111111,0.938007,190,194.569,0.0284307
 186.264,0.016572,0.00111111,0.937797,232,195.513,0.0210752
 249.948,0.0194051,0.00111111,0.91653,246,262.158,0.0215199
 240.864,0.0182591,0.00111111,0.919563,188,251.577,0.0306745
 184.618,0.0171253,0.00111111,0.938346,222,193.849,0.0300316
 213.473,0.0190352,0.00111111,0.92871,275,224.14,0.0207037
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all.gnuplot.fit.log
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all.gnuplot.fit.log
@ -0,0 +1,138 @@
 *******************************************************************************
 Sun Oct  1 20:05:21 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times-all.csv" every ::1 using 2:5
        format = x:z
        #datapoints = 200
        residuals are weighted equally (unit weight)
 function used for fitting: f(x)
 fitted parameters initialized with current variable values
 Iteration 0
 WSSR        : 8.65799e+06       delta(WSSR)/WSSR   : 0
 delta(WSSR) : 0                 limit for stopping : 1e-05
 lambda	  : 0.707234
 initial set of free parameter values
 a               = 1
 b               = 1
 After 5 iterations the fit converged.
 final sum of squares of residuals : 387750
 rel. change during last iteration : -1.80465e-10
 degrees of freedom    (FIT_NDF)                        : 198
 rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 44.2531
 variance of residuals (reduced chisquare) = WSSR/ndf   : 1958.33
 Final set of parameters            Asymptotic Standard Error
 =======================            ==========================
 a               = -7207.93         +/- 1699         (23.57%)
 b               = 339.971          +/- 32.22        (9.477%)
 correlation matrix of the fit parameters:
               a      b      
 a               1.000 
 b              -0.995  1.000 
 *******************************************************************************
 Sun Oct  1 20:05:21 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times-all.csv" every ::1 using 4:5
        format = x:z
        #datapoints = 200
        residuals are weighted equally (unit weight)
 function used for fitting: g(x)
 fitted parameters initialized with current variable values
 Iteration 0
 WSSR        : 8.58412e+06       delta(WSSR)/WSSR   : 0
 delta(WSSR) : 0                 limit for stopping : 1e-05
 lambda	  : 0.965888
 initial set of free parameter values
 aa              = 1
 bb              = 1
 After 5 iterations the fit converged.
 final sum of squares of residuals : 374307
 rel. change during last iteration : -1.28123e-12
 degrees of freedom    (FIT_NDF)                        : 198
 rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 43.4792
 variance of residuals (reduced chisquare) = WSSR/ndf   : 1890.44
 Final set of parameters            Asymptotic Standard Error
 =======================            ==========================
 aa              = 2485.68          +/- 489.8        (19.71%)
 bb              = -2109            +/- 455.8        (21.61%)
 correlation matrix of the fit parameters:
               aa     bb     
 aa              1.000 
 bb             -1.000  1.000 
 *******************************************************************************
 Sun Oct  1 20:05:21 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times-all.csv" every ::1 using 4:6
        format = x:z
        #datapoints = 200
        residuals are weighted equally (unit weight)
 function used for fitting: h(x)
 fitted parameters initialized with current variable values
 Iteration 0
 WSSR        : 9.43971e+06       delta(WSSR)/WSSR   : 0
 delta(WSSR) : 0                 limit for stopping : 1e-05
 lambda	  : 0.965888
 initial set of free parameter values
 aaa             = 1
 bbb             = 1
 After 5 iterations the fit converged.
 final sum of squares of residuals : 11.3578
 rel. change during last iteration : -7.81502e-08
 degrees of freedom    (FIT_NDF)                        : 198
 rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.239505
 variance of residuals (reduced chisquare) = WSSR/ndf   : 0.0573625
 Final set of parameters            Asymptotic Standard Error
 =======================            ==========================
 aaa             = -3135.44         +/- 2.698        (0.08605%)
 bbb             = 3135.83          +/- 2.511        (0.08006%)
 correlation matrix of the fit parameters:
               aaa    bbb    
 aaa             1.000 
 bbb            -1.000  1.000 
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all.gnuplot.log
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all.gnuplot.log
@ -0,0 +1,261 @@
 Iteration 0
 WSSR        : 8.65799e+06       delta(WSSR)/WSSR   : 0
 delta(WSSR) : 0                 limit for stopping : 1e-05
 lambda	  : 0.707234
 initial set of free parameter values
 a               = 1
 b               = 1
 /
 Iteration 1
 WSSR        : 422995            delta(WSSR)/WSSR   : -19.4683
 delta(WSSR) : -8.235e+06        limit for stopping : 1e-05
 lambda	  : 0.0707234
 resultant parameter values
 a               = -4.94625
 b               = 203.522
 /
 Iteration 2
 WSSR        : 415042            delta(WSSR)/WSSR   : -0.0191613
 delta(WSSR) : -7952.76          limit for stopping : 1e-05
 lambda	  : 0.00707234
 resultant parameter values
 a               = -864.859
 b               = 220.257
 /
 Iteration 3
 WSSR        : 387879            delta(WSSR)/WSSR   : -0.0700308
 delta(WSSR) : -27163.5          limit for stopping : 1e-05
 lambda	  : 0.000707234
 resultant parameter values
 a               = -6772.19
 b               = 331.747
 /
 Iteration 4
 WSSR        : 387750            delta(WSSR)/WSSR   : -0.000332164
 delta(WSSR) : -128.797          limit for stopping : 1e-05
 lambda	  : 7.07234e-05
 resultant parameter values
 a               = -7207.61
 b               = 339.965
 /
 Iteration 5
 WSSR        : 387750            delta(WSSR)/WSSR   : -1.80465e-10
 delta(WSSR) : -6.99755e-05      limit for stopping : 1e-05
 lambda	  : 7.07234e-06
 resultant parameter values
 a               = -7207.93
 b               = 339.971
 After 5 iterations the fit converged.
 final sum of squares of residuals : 387750
 rel. change during last iteration : -1.80465e-10
 degrees of freedom    (FIT_NDF)                        : 198
 rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 44.2531
 variance of residuals (reduced chisquare) = WSSR/ndf   : 1958.33
 Final set of parameters            Asymptotic Standard Error
 =======================            ==========================
 a               = -7207.93         +/- 1699         (23.57%)
 b               = 339.971          +/- 32.22        (9.477%)
 correlation matrix of the fit parameters:
               a      b      
 a               1.000 
 b              -0.995  1.000 
 Iteration 0
 WSSR        : 8.58412e+06       delta(WSSR)/WSSR   : 0
 delta(WSSR) : 0                 limit for stopping : 1e-05
 lambda	  : 0.965888
 initial set of free parameter values
 aa              = 1
 bb              = 1
 /
 Iteration 1
 WSSR        : 418736            delta(WSSR)/WSSR   : -19.5001
 delta(WSSR) : -8.16538e+06      limit for stopping : 1e-05
 lambda	  : 0.0965888
 resultant parameter values
 aa              = 112.257
 bb              = 99.0225
 /
 Iteration 2
 WSSR        : 395337            delta(WSSR)/WSSR   : -0.0591881
 delta(WSSR) : -23399.2          limit for stopping : 1e-05
 lambda	  : 0.00965888
 resultant parameter values
 aa              = 852.014
 bb              = -588.836
 /
 Iteration 3
 WSSR        : 374316            delta(WSSR)/WSSR   : -0.0561565
 delta(WSSR) : -21020.3          limit for stopping : 1e-05
 lambda	  : 0.000965888
 resultant parameter values
 aa              = 2450.37
 bb              = -2076.15
 /
 Iteration 4
 WSSR        : 374307            delta(WSSR)/WSSR   : -2.6247e-05
 delta(WSSR) : -9.82442          limit for stopping : 1e-05
 lambda	  : 9.65888e-05
 resultant parameter values
 aa              = 2485.68
 bb              = -2109
 /
 Iteration 5
 WSSR        : 374307            delta(WSSR)/WSSR   : -1.28123e-12
 delta(WSSR) : -4.79573e-07      limit for stopping : 1e-05
 lambda	  : 9.65888e-06
 resultant parameter values
 aa              = 2485.68
 bb              = -2109
 After 5 iterations the fit converged.
 final sum of squares of residuals : 374307
 rel. change during last iteration : -1.28123e-12
 degrees of freedom    (FIT_NDF)                        : 198
 rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 43.4792
 variance of residuals (reduced chisquare) = WSSR/ndf   : 1890.44
 Final set of parameters            Asymptotic Standard Error
 =======================            ==========================
 aa              = 2485.68          +/- 489.8        (19.71%)
 bb              = -2109            +/- 455.8        (21.61%)
 correlation matrix of the fit parameters:
               aa     bb     
 aa              1.000 
 bb             -1.000  1.000 
 Iteration 0
 WSSR        : 9.43971e+06       delta(WSSR)/WSSR   : 0
 delta(WSSR) : 0                 limit for stopping : 1e-05
 lambda	  : 0.965888
 initial set of free parameter values
 aaa             = 1
 bbb             = 1
 /
 Iteration 1
 WSSR        : 82262.8           delta(WSSR)/WSSR   : -113.751
 delta(WSSR) : -9.35745e+06      limit for stopping : 1e-05
 lambda	  : 0.0965888
 resultant parameter values
 aaa             = 93.9799
 bbb             = 130.237
 /
 Iteration 2
 WSSR        : 38961.1           delta(WSSR)/WSSR   : -1.11141
 delta(WSSR) : -43301.7          limit for stopping : 1e-05
 lambda	  : 0.00965888
 resultant parameter values
 aaa             = -912.157
 bbb             = 1067.01
 /
 Iteration 3
 WSSR        : 29.5535           delta(WSSR)/WSSR   : -1317.32
 delta(WSSR) : -38931.6          limit for stopping : 1e-05
 lambda	  : 0.000965888
 resultant parameter values
 aaa             = -3087.39
 bbb             = 3091.12
 /
 Iteration 4
 WSSR        : 11.3578           delta(WSSR)/WSSR   : -1.60205
 delta(WSSR) : -18.1958          limit for stopping : 1e-05
 lambda	  : 9.65888e-05
 resultant parameter values
 aaa             = -3135.43
 bbb             = 3135.82
 /
 Iteration 5
 WSSR        : 11.3578           delta(WSSR)/WSSR   : -7.81502e-08
 delta(WSSR) : -8.87612e-07      limit for stopping : 1e-05
 lambda	  : 9.65888e-06
 resultant parameter values
 aaa             = -3135.44
 bbb             = 3135.83
 After 5 iterations the fit converged.
 final sum of squares of residuals : 11.3578
 rel. change during last iteration : -7.81502e-08
 degrees of freedom    (FIT_NDF)                        : 198
 rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.239505
 variance of residuals (reduced chisquare) = WSSR/ndf   : 0.0573625
 Final set of parameters            Asymptotic Standard Error
 =======================            ==========================
 aaa             = -3135.44         +/- 2.698        (0.08605%)
 bbb             = 3135.83          +/- 2.511        (0.08006%)
 correlation matrix of the fit parameters:
               aaa    bbb    
 aaa             1.000 
 bbb            -1.000  1.000 
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all.gnuplot.script
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all.gnuplot.script
@ -0,0 +1,20 @@
 set datafile separator ","
 f(x)=a*x+b
 fit f(x) "20170830-evolution1D_5x5_100Times-all.csv" every ::1 using 2:5 via a,b
 set terminal png
 set xlabel 'regularity'
 set ylabel 'steps'
 set output "20170830-evolution1D_5x5_100Times-all_regularity-vs-steps.png"
 plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 2:5 title "20170830-evolution1D_5x5_100Times.csv", "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 2:5 title "20170830-evolution1D_5x5_100Times-added_one.csv", f(x) title "lin. fit" lc rgb "black"
 g(x)=aa*x+bb
 fit g(x) "20170830-evolution1D_5x5_100Times-all.csv" every ::1 using 4:5 via aa,bb
 set xlabel 'improvement potential'
 set ylabel 'steps'
 set output "20170830-evolution1D_5x5_100Times-all_improvement-vs-steps.png"
 plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:5 title "20170830-evolution1D_5x5_100Times.csv", "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:5 title "20170830-evolution1D_5x5_100Times-added_one.csv", g(x) title "lin. fit" lc rgb "black"
 h(x)=aaa*x+bbb
 fit h(x) "20170830-evolution1D_5x5_100Times-all.csv" every ::1 using 4:6 via aaa,bbb
 set xlabel 'improvement potential'
 set ylabel 'evolution error'
 set output "20170830-evolution1D_5x5_100Times-all_improvement-vs-evo-error.png"
 plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:6 title "20170830-evolution1D_5x5_100Times.csv", "20170830-evolution1D_5x5_100Times-added_one.csv" every ::1 using 4:6 title "20170830-evolution1D_5x5_100Times-added_one.csv", h(x) title "lin. fit" lc rgb "black"
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all_improvement-vs-evo-error.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all_improvement-vs-evo-error.png
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all_improvement-vs-steps.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all_improvement-vs-steps.png
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all_regularity-vs-steps.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times-all_regularity-vs-steps.png
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times.gnuplot.fit.log
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times.gnuplot.fit.log
@ -1,7 +1,7 @@
 *******************************************************************************
-Wed Aug 30 21:11:12 2017
+Sun Oct  1 19:58:40 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times.csv" every ::1 using 2:5
@ -47,7 +47,7 @@ b              -0.995  1.000
 *******************************************************************************
-Wed Aug 30 21:11:12 2017
+Sun Oct  1 19:58:40 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:5
@ -93,7 +93,7 @@ bb             -1.000  1.000
 *******************************************************************************
-Wed Aug 30 21:11:12 2017
+Sun Oct  1 19:58:40 2017
 FIT:    data read from "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:6
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times.gnuplot.script
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times.gnuplot.script
@ -2,13 +2,19 @@ set datafile separator ","
 f(x)=a*x+b
 fit f(x) "20170830-evolution1D_5x5_100Times.csv" every ::1 using 2:5 via a,b
 set terminal png
 set xlabel 'regularity'
 set ylabel 'steps'
 set output "20170830-evolution1D_5x5_100Times_regularity-vs-steps.png"
-plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 2:5 title "regularity vs. steps", f(x) lc rgb "black"
+plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 2:5 title "data", f(x) title "lin. fit" lc rgb "black"
 g(x)=aa*x+bb
 fit g(x) "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:5 via aa,bb
 set xlabel 'improvement potential'
 set ylabel 'steps'
 set output "20170830-evolution1D_5x5_100Times_improvement-vs-steps.png"
-plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:5 title "improvement potential vs. steps", g(x) lc rgb "black"
+plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:5 title "data", g(x) title "lin. fit" lc rgb "black"
 h(x)=aaa*x+bbb
 fit h(x) "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:6 via aaa,bbb
 set xlabel 'improvement potential'
 set ylabel 'evolution error'
 set output "20170830-evolution1D_5x5_100Times_improvement-vs-evo-error.png"
-plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:6 title "improvement potential vs. evolution error", h(x) lc rgb "black"
+plot "20170830-evolution1D_5x5_100Times.csv" every ::1 using 4:6 title "data", h(x) title "lin. fit" lc rgb "black"
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times_improvement-vs-evo-error.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times_improvement-vs-evo-error.png
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times_improvement-vs-steps.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times_improvement-vs-steps.png
--- a/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times_regularity-vs-steps.png
+++ b/dokumentation/evolution1d/20170830-evolution1D_5x5_100Times_regularity-vs-steps.png
--- a/dokumentation/evolution1d/combine.sh
+++ b/dokumentation/evolution1d/combine.sh
@ -0,0 +1,33 @@
 #!/bin/bash
 if [[ $# -eq 0 ]]; then
    echo "usage: $0 <DATA.csv>"
 else
    data="$1";
    png="`echo $1 | sed -s "s/\.csv$//"`" # strip ending
    (cat <<EOD
 set datafile separator ","
 f(x)=a*x+b
 fit f(x) "$data" every ::1 using 2:5 via a,b
 set terminal png
 set xlabel 'regularity'
 set ylabel 'steps'
 set output "${png}_regularity-vs-steps.png"
 plot "$2" every ::1 using 2:5 title "$2", "$3" every ::1 using 2:5 title "$3", f(x) title "lin. fit" lc rgb "black"
 g(x)=aa*x+bb
 fit g(x) "$data" every ::1 using 4:5 via aa,bb
 set xlabel 'improvement potential'
 set ylabel 'steps'
 set output "${png}_improvement-vs-steps.png"
 plot "$2" every ::1 using 4:5 title "$2", "$3" every ::1 using 4:5 title "$3", g(x) title "lin. fit" lc rgb "black"
 h(x)=aaa*x+bbb
 fit h(x) "$data" every ::1 using 4:6 via aaa,bbb
 set xlabel 'improvement potential'
 set ylabel 'evolution error'
 set output "${png}_improvement-vs-evo-error.png"
 plot "$2" every ::1 using 4:6 title "$2", "$3" every ::1 using 4:6 title "$3", h(x) title "lin. fit" lc rgb "black"
 EOD
 ) > "${png}.gnuplot.script" 
    gnuplot "${png}.gnuplot.script" 2> "${png}.gnuplot.log"
    mv fit.log "${png}.gnuplot.fit.log"
 fi
--- a/dokumentation/evolution1d/images.sh
+++ b/dokumentation/evolution1d/images.sh
@ -10,16 +10,22 @@ set datafile separator ","
 f(x)=a*x+b
 fit f(x) "$data" every ::1 using 2:5 via a,b
 set terminal png
 set xlabel 'regularity'
 set ylabel 'steps'
 set output "${png}_regularity-vs-steps.png"
-plot "$data" every ::1 using 2:5 title "regularity vs. steps", f(x) lc rgb "black"
+plot "$data" every ::1 using 2:5 title "data", f(x) title "lin. fit" lc rgb "black"
 g(x)=aa*x+bb
 fit g(x) "$data" every ::1 using 4:5 via aa,bb
 set xlabel 'improvement potential'
 set ylabel 'steps'
 set output "${png}_improvement-vs-steps.png"
-plot "$data" every ::1 using 4:5 title "improvement potential vs. steps", g(x) lc rgb "black"
+plot "$data" every ::1 using 4:5 title "data", g(x) title "lin. fit" lc rgb "black"
 h(x)=aaa*x+bbb
 fit h(x) "$data" every ::1 using 4:6 via aaa,bbb
 set xlabel 'improvement potential'
 set ylabel 'evolution error'
 set output "${png}_improvement-vs-evo-error.png"
-plot "$data" every ::1 using 4:6 title "improvement potential vs. evolution error", h(x) lc rgb "black"
+plot "$data" every ::1 using 4:6 title "data", h(x) title "lin. fit" lc rgb "black"
 EOD
 ) > "${png}.gnuplot.script" 
    gnuplot "${png}.gnuplot.script" 2> "${png}.gnuplot.log"