X-Git-Url: https://bilbo.iut-bm.univ-fcomte.fr/and/gitweb/book_chic.git/blobdiff_plain/0705dd41d0c66269b8b97d2144064e58423b489c..a5f58fd899d0066c8331580c1ee5024a4c411990:/chapter2.tex?ds=inline diff --git a/chapter2.tex b/chapter2.tex index f3a2509..b50c9dd 100644 --- a/chapter2.tex +++ b/chapter2.tex @@ -29,7 +29,7 @@ gradually being supplemented by the processing of modal, frequency and, recently, interval and fuzzy variables. } -\section{Preamble} +\section*{Preamble} Human operative knowledge is mainly composed of two components: that of facts and that of rules between facts or between rules themselves. @@ -101,3 +101,1083 @@ index of this selected association is multivariate~\cite{Bernard}. +Moreover, to our knowledge, on the one hand, most often the different +and interesting developments focus on proposals for a partial +implication index for binary data~\cite{Lermana} or \cite{Lallich}, on +the other hand, this notion is not extended to other types of +variables, to extraction and representation according to a rule graph +or a hierarchy of meta-rules; structures aiming at access to the +meaning of a whole not reduced to the sum of its +parts~\cite{Seve}\footnote{This is what the philosopher L. Sève + emphasizes :"... in the non-additive, non-linear passage of the + parts to the whole, there are properties that are in no way + precontained in the parts and which cannot therefore be explained by + them" }, i.e. operating as a complex non-linear system. +For example, it is well known, through usage, that the meaning of a +sentence does not completely depend on the meaning of each of the +words in it (see the previous chapter, point 4). + +Let us return to what we believe is fertile in the approach we are +developing. +It would seem that, in the literature, the notion of implication index +is also not extended to the search for subjects and categories of +subjects responsible for associations. +Nor that this responsibility is quantified and thus leads to a +reciprocal structuring of all subjects, conditioned by their +relationships to variables. +We propose these extensions here after recalling the founding +paradigm. + + +\section{Implication intensity in the binary case} + +\subsection{Fundamental and founding situation} + +A set of objects or subjects E is crossed with variables +(characters, criteria, successes,...) which are interrogated as +follows: "to what extent can we consider that instantiating variable\footnote{Throughout the book, the word "variable" refers to both an isolated variable in premise (example: "to be blonde") or a conjunction of isolated variables (example: "to be blonde and to be under 30 years old and to live in Paris")} $a$ +implies instantiating variable $b$? +In other words, do the subjects tend to be $b$ if we know that they are +$a$?". +In natural, human or life sciences situations, where theorems (if $a$ +then $b$) in the deductive sense of the term cannot be established +because of the exceptions that taint them, it is important for the +researcher and the practitioner to "mine into his data" in order to +identify sufficiently reliable rules (kinds of "partial theorems", +inductions) to be able to conjecture\footnote{"The exception confirms the rule", as the popular saying goes, in the sense that there would be no exceptions if there were no rule} a possible causal relationship, +a genesis, to describe, structure a population and make the assumption +of a certain stability for descriptive and, if possible, predictive +purposes. +But this excavation requires the development of methods to guide it +and to free it from trial and error and empiricism. + + +\subsection{Mathematization} + +To do this, following the example of the I.C. Lerman similarity +measurement method \cite{Lerman,Lermanb}, following the classic +approach in non-parametric tests (e. g. Fischer, Wilcoxon, etc.), we +define~\cite{Grasb,Grasf} the confirmatory quality measure of the +implicative relationship $a \Rightarrow b$ from the implausibility of +the occurrence in the data of the number of cases that invalidate it, +i.e. for which $a$ is verified without $b$ being verified. This +amounts to comparing the difference between the quota and the +theoretical if only chance occurred\footnote{"...[in agreement with + Jung] if the frequency of coincidences does not significantly + exceed the probability that they can be calculated by attributing + them solely by chance to the exclusion of hidden causal + relationships, we certainly have no reason to suppose the existence + of such relationships.", H. Atlan~\cite{Atlana}}. +But when analyzing data, it is this gap that we take into account and +not the statement of a rejection or null hypothesis eligibility. +This measure is relative to the number of data verifying $a$ and not +$b$ respectively, the circumstance in which the involvement is +precisely put in default. +It quantifies the expert's "astonishment" at the unlikely small number +of counter-examples in view of the supposed independence between the +variables and the numbers involved. + +Let us be clear. A finite set $V$ of $v$ variables is given: $a$, $b$, +$c$,... +In the classical paradigmatic situation and initially retained, it is +about the performance (success-failure) to items of a questionnaire. +To a finite set $E$ of $n$ subjects $x$, functions of the type : $x +\rightarrow a(x)$ where $a(x) = 1$ (or $a(x) = true$) if $x$ satisfies +or has the character $a$ and $0$ (or $a(x) = false$) otherwise are +associated by abuse of writing. +In artificial intelligence, we will say that $x$ is an example or an +instance for $a$ if $a(x) = 1$ and a counter-example if not. + + +The $a \Rightarrow b$ rule is logically true if for any $x$ in the +sample, $b(x)$ is null only if $a(x)$ is also null; in other words if +set $A$ of the $x$ for which $a(x)=1$ is contained in set $B$ of the +$x$ for which $b(x)=1$. +However, this strict inclusion is only exceptionally observed in the +pragmatically encountered experiments. +In the case of a knowledge questionnaire, we could indeed observe a +few rare students passing an item $a$ and not passing item $b$, +without contesting the tendency to pass item $b$ when we have passed +item $a$. +With regard to the cardinals of $E$ (of size $n$), but also of $A$ (or +$n_a$) and $B$ (or $n_b$), it is therefore the "weight" of the +counter-examples (or) that must be taken into account in order to +statistically accept whether or not to keep the quasi-implication or +quasi-rule $a \Rightarrow b$. Thus, it is from the dialectic of +example-counter-examples that the rule appears as the overcoming of +contradiction. + +\subsection{Formalization} + +To formalize this quasi-rule, we consider any two parts $X$ and $Y$ of +$E$, chosen randomly and independently (absence of a priori link +between these two parts) and of the same respective cardinals as $A$ +and $B$. Let $\overline{Y}$ and $\overline{B}$ be the respective complementary of $Y$ and $B$ in $E$ of the same cardinal $n_{\overline{b}}= n-n_b$. + +We will then say: + +\definition $a \Rightarrow b$ is acceptable at confidence level +$1-\alpha$ if and only if +$$Pr[Card(X\cap \overline{Y})\leq card(A\cap \overline{B})]\leq \alpha$$ + +\begin{figure}[htbp] + \centering +\includegraphics[scale=0.34]{chap2fig1.png} + \caption{The dark grey parts correspond to the counter-examples of the + implication $a \Rightarrow b$} +\label{chap2fig1} +\end{figure} + +It is established \cite{Lermanb} that, for a certain drawing process, +the random variable $Card(X\cap \overline{Y})$ follows the Poisson law +of parameter $\frac{n_a n_{\overline{b}}}{n}$. +We achieve this same result by proceeding differently in the following +way: + +Note $X$ (resp. $Y$) the random subset of binary transactions where +$a$ (resp. $b$) would appear, independently, with the frequency +$\frac{n_a}{n}$ (resp. $\frac{n_b}{n}$). +To specify how the transactions specified in variables $a$ and $b$, +respectively $A$ and $B$, are extracted, for example, the following +semantically permissible assumptions are made regarding the +observation of the event: $[a=1~ and~ b=0]$. $(A\cap +\overline{B})$\footnote{We then note $\overline{v}$ the variable + negation of $v$ (or $not~ v$) and $\overline{P}$ the complementary + part of the part P of E.} is the subset of transactions, +counter-examples of implication $a \Rightarrow b$: + +Assumptions: +\begin{itemize} +\item h1: the waiting times of an event $[a~ and~ not~ b]$ are independent + random variables; +\item h2: the law of the number of events occurring in the time + interval $[t,~ t+T[$ depends only on T; +\item h3: two such events cannot occur simultaneously +\end{itemize} + +It is then demonstrated (for example in~\cite{Saporta}) that the +number of events occurring during a period of fixed duration $n$ +follows a Poisson's law of parameter $c.n$ where $c$ is called the +rate of the apparitions process during the unit of time. + + +However, for each transaction assumed to be random, the event $[a=1]$ +has the probability of the frequency $\frac{n_a}{n}$, the event[b=0] +has as probability the frequency, therefore the joint event $[a=1~ + and~ b=0]$ has for probability estimated by the frequency +$\frac{n_a}{n}. \frac{n_{\overline{b}}}{b}$ in the hypothesis of absence of an a priori link between a and b (independence). + +We can then estimate the rate $c$ of this event by $\frac{n_a}{n}. \frac{n_{\overline{b}}}{b}$. + +Thus for a duration of time $n$, the occurrences of the event $[a~ and~ not~b]$ follow a Poisson's law of parameter : +$$\lambda = \frac{n_a.n_{\overline{b}}}{n}$$ + +As a result, $Pr[Card(X\cap \overline{Y})= s]= e^{-\lambda}\frac{\lambda^s}{s!}$ + +Consequently, the probability that the hazard will lead, under the +assumption of the absence of an a priori link between $a$ and $b$, to +more counter-examples than those observed is: + +$$Pr[Card(X\cap \overline{Y})\leq card(A\cap \overline{B})] = +\sum^{card(A\cap \overline{B})}_{s=0} e^{-\lambda}\frac{\lambda^s}{s!} $$ + + But other legitimate drawing processes lead to a binomial law, or + even a hypergeometric law (itself not semantically adapted to the + situation because of its symmetry). Under suitable convergence + conditions, these two laws are finally reduced to the Poisson Law + above (see Annex to this chapter). + +If $n_{\overline{b}}\neq 0$, we reduce and center this Poison variable +into the variable: + +$$Q(a,\overline{b})= \frac{card(X \cap \overline{Y})) - \frac{n_a.n_{\overline{b}}}{n}}{\sqrt{\frac{n_a.n_{\overline{b}}}{n}}} $$ + +In the experimental realization, the observed value of +$Q(a,\overline{b})$ is $q(a,\overline{b})$. +It estimates a gap between the contingency $(card(A\cap +\overline{B}))$ and the value it would have taken if there had been +independence between $a$ and $b$. + +\definition +\begin{equation} q(a,\overline{b}) = \frac{n_{a \wedge \overline{b}}- + \frac{n_a.n_{\overline{b}}}{n}}{\sqrt{\frac{n_a.n_{\overline{b}}}{n}}} + \label{eq2.1} +\end{equation} +is called the implication index, the number used as an indicator of +the non-implication of $a$ to $b$. +In cases where the approximation is properly legitimized (for example +$\frac{n_a.n_{\overline{b}}}{n}\geq 4$), the variable +$Q(a,\overline{b})$ approximately follows the reduced centered normal +distribution. The intensity of implication, measuring the quality of +$a\Rightarrow b$, for $n_a\leq n_b$ and $nb \neq n$, is then defined +from the index $q(a,\overline{b})$ by: + +\definition +The implication intensity that measures the inductive quality of a +over b is: +$$\varphi(a,b)=1-Pr[Q(a,\overline{b})\leq q(a,\overline{b})] = +\frac{1}{\sqrt{2 \pi}} \int^{\infty}_{ q(a,\overline{b})} +e^{-\frac{t^2}{2}} dt,~ if~ n_b \neq n$$ +$$\varphi(a,b)=0,~ otherwise$$ +As a result, the definition of statistical implication becomes: +\definition +Implication $a\Rightarrow b$ is admissible at confidence level +$1-\alpha $ if and only if: +$$\varphi(a,b)\geq 1-\alpha$$ + + +It should be recalled that this modeling of quasi-implication measures +the astonishment to note the smallness of counter-examples compared to +the surprising number of instances of implication. +It is a measure of the inductive and informative quality of +implication. Therefore, if the rule is trivial, as in the case where +$B$ is very large or coincides with $E$, this astonishment becomes +small. +We also demonstrate~\cite{Grasf} that this triviality results in a +very low or even zero intensity of implication: If, $n_a$ being fixed +and $A$ being included in $B$, $n_b$ tends towards $n$ ($B$ "grows" +towards $E$), then $\varphi(a,b)$ tends towards $0$. We therefore +define, by "continuity":$\varphi(a,b) = 0$ if $n_b = n$. Similarly, if +$A\subset B$, $\varphi(a,b)$ may be less than $1$ in the case where +the inductive confidence, measured by statistical surprise, is +insufficient. + +{\bf \remark Total correlation, partial correlation} + + +We take here the notion of correlation in a more general sense than +that used in the domain that develops the linear correlation +coefficient (linear link measure) or the correlation ratio (functional +link measure). +In our perspective, there is a total (or partial) correlation between +two variables $a$ and $b$ when the respective events they determine +occur (or almost occur) at the same time, as well as their opposites. +However, we know from numerical counter-examples that correlation and +implication do not come down to each other, that there can be +correlation without implication and vice versa~\cite{Grasf} and below. +If we compare the implication coefficient and the linear correlation +coefficient algebraically, it is clear that the two concepts do not +coincide and therefore do not provide the same +information\footnote{"More serious is the logical error inferred from + a correlation found to the existence of a causality" writes Albert + Jacquard in~\cite{Jacquard}, p.159. }. + +The quasi-implication of non-symmetric index $q(a,\overline{b})$ does +not coincide with the correlation coefficient $\rho(a, b)$ which is +symmetric and which reflects the relationship between variables a and +b. Indeed, we show~\cite{Grasf} that if $q(a,\overline{b}) \neq 0$ +then +$$\frac{\rho(a,b)}{q(a,\overline{b})} = \sqrt{\frac{n}{n_b + n_{\overline{a}}}} q(a,\overline{b})$$ +With the correlation considered from the point of view of linear +correlation, even if correlation and implication are rather in the +same direction, the orientation of the relationship between two +variables is not transparent because it is symmetrical, which is not +the bias taken in the SIA. +From a statistical relationship given by the correlation, two opposing +empirical propositions can be deduced. + +The following dual numerical situation clearly illustrates this: + + +\begin{table}[htp] +\center +\begin{tabular}{|l|c|c|c|}\hline +\diagbox[width=4em]{$a_1$}{$b_1$}& + 1 & 0 & margin\\ \hline + 1 & 96 & 4& 100 \\ \hline + 0 & 50 & 50& 100 \\ \hline + margin & 146 & 54& 200 \\ \hline +\end{tabular} ~ ~ ~ ~ ~ ~ ~ \begin{tabular}{|l|c|c|c|}\hline +\diagbox[width=4em]{$a_2$}{$b_2$}& + 1 & 0 & margin\\ \hline + 1 & 94 & 6& 100 \\ \hline + 0 & 52 & 48& 100 \\ \hline + margin & 146 & 54& 200 \\ \hline +\end{tabular} + +\caption{Numeric example of difference between implication and + correlation} +\label{chap2tab1} +\end{table} + +In Table~\ref{chap2tab1}, the following correlation and implications +can be computed:\\ +Correlation $\rho(a_1,b_1)=0.468$, Implication +$q(a_1,\overline{b_1})=-4.082$\\ +Correlation $\rho(a_2,b_2)=0.473$, Implication $q(a_2,\overline{b_2})=-4.041$ + + +Thus, we observe that, on the one hand, $a_1$ and $b_1$ are less +correlated than $a_2$ and $b_2$ while, on the other hand, the +implication intensity of $a_1$ over $b_1$ is higher than that of $a_2$ +over $b_2$ since $q1 + 0 + \label{eq2.3} +\end{equation} + + +\begin{equation} + \frac{\partial + q}{\partial n_{a \wedge + \overline{b}}} = \frac{1}{\sqrt{\frac{n_a n_{\overline{b}}}{n}}} + = \frac{1}{\sqrt{\frac{n_a (n-n_b)}{n}}} > 0 + \label{eq2.4} +\end{equation} + + +Thus, if the increases $\Delta nb$ and $\Delta n_{a \wedge + \overline{b}}$ are positive, the increase of $q(a,\overline{b})$ is +also positive. This is interpreted as follows: if the number of +examples of $b$ and the number of counter-examples of implication +increase then the intensity of implication decreases for $n$ and $n_a$ +constant. In other words, this intensity of implication is maximum at +observed values $n_b$ and $ n_{a \wedge + \overline{b}}$ and minimum at values $n_b+\Delta n_b$ and $n_{a \wedge + \overline{b}}+ n_{a \wedge + \overline{b}}$. + +If we examine the case where $n_a$ varies, we obtain the partial +derivative of $q$ with respect to $n_a$ which is: + +\begin{equation} + C = \frac{ n_{a \wedge \overline{b}}}{2 + \sqrt{\frac{n_{\overline{b}}}{n}}} + \left(\frac{n}{n_a}\right)^{\frac{3}{2}} + -\frac{1}{2}\sqrt{\frac{n_{\overline{b}}}{n_a}}<0 + \label{eq2.5} + \end{equation} + +Thus, for variations of $n_a$ on $[0,~ nb]$, the implication index function is always decreasing (and concave) with respect to $n_a$ and is therefore minimum for $n_a= n_b$. As a result, the intensity of implication is increasing and maximum for $n_a= n_b$. + +Note the partial derivative of $q$ with respect to $n$: + +$$\frac{\partial q}{\partial n} = \frac{1}{2\sqrt{n}} \left( n_{a + \wedge \overline{b}}+\frac{n_a n_{\overline{b}}}{n} \right)$$ + +Consequently, if the other 3 parameters are constant, the implication +index decreases by $\sqrt{n}$. +The quality of implication is therefore all the better, a specific +property of the SIA compared to other indicators used in the +literature~\cite{Grasab}. +This property is in accordance with statistical and semantic +expectations regarding the credit given to the frequency of +observations. +Since the partial derivatives of $q$ (at least one of them) are +non-linear according to the variable parameters involved, we are +dealing with a non-linear dynamic system\footnote{"Non-linear systems + are systems that are known to be deterministic but for which, in + general, nothing can be predicted because calculations cannot be + made"~\cite{Ekeland} p. 265.} with all the epistemological +consequences that we will consider elsewhere. + + + +\subsection{Numerical example} +In a first experiment, we observe the occurrences: $n = 100$, $n_a = +20$, $n_b = 40$ (hence $n_b=60$, $ n_{a \wedge \overline{b}} = 4$). +The application of formula (\ref{eq2.1}) gives = -2.309. +In a 2nd experiment, $n$ and $n_a$ are unchanged but the occurrences +of $b$ and counter-examples $n_{a \wedge \overline{b}}$ increase by one unit. + +At the initial point of the space of the 4 variables, the partial +derivatives that only interest us (according to $n_b$ and $n_{a + \wedge \overline{b}}$) have respectively the following values when +applying formulas (\ref{eq2.3}) and (\ref{eq2.4}): $\frac{\partial + q}{\partial n_b} = 0.0385$ and $\frac{\partial q}{\partial n_{a + \wedge \overline{b}}} = 0.2887$. + +As $\Delta n_b$, $\Delta n_{\overline{b}}$ and $\Delta n_{a + \wedge \overline{b}} $ are equal to 1, -1 and 1, then $\Delta q$ is +equal to: $0.0385 + 0.2887 + o(\Delta q) = 0.3272 + o(\Delta q)$ and +the approximate value of $q$ in the second experiment is $-2.309 + +0.2887 + o(\Delta q)= -1.982 +o(\Delta q)$ using the first order +development of $q$ (formula (\ref{eq2.2})). +However, the calculation of the new implication index $q$ at the point +of the 2nd experiment is, by the use of (\ref{eq2.1}): $-1.9795$, a +value well approximated by the development of $q$. + + + +\subsection{A first differential relationship of $\varphi$ as a function of function $q$} +Let us consider the intensity of implication $\varphi$ as a function +of $q(a,\overline{b})$: +$$\varphi(q)=\frac{1}{\sqrt{2\pi}}\int_q^{\infty}e^{-\frac{t^2}{2}}$$ +We can then examine how $\varphi(q)$ varies when $q$ varies in the neighberhood of a given value $(a,b)$, knowing how $q$ itself varies according to the 4 parameters that determine it. By derivation of the integration bound, we obtain: +\begin{equation} + \frac{d\varphi}{dq}=-\frac{1}{\sqrt{2\pi}}e^{-\frac{q^2}{2}} < 0 + \label{eq2.6} +\end{equation} +This confirms that the intensity increases when $q$ decreases, but the growth rate is specified by the formula, which allows us to study more precisely the variations of $\varphi$. Since the derivative of $\varphi$ from $q$ is always negative, the function $\varphi$ is decreasing. + +{\bf Numerical example}\\ +Taking the values of the occurrences observed in the 2 experiments +mentioned above, we find for $q = -2.309$, the value of the intensity +of implication $\varphi(q)$ is equal to 0.992. Applying formula +(\ref{eq2.6}), the derivative of $\varphi$ with respect to $q$ is: +-0.02775 and the negative increase in intensity is then: -0.02775, +$\Delta q$ = 0.3272. The approximate first-order intensity is +therefore: $0.992-\Delta q$ or 0.983. However, the actual calculation +of this intensity is, for $q= -1.9795$, $\varphi(q) = 0.976$. + + + +\subsection{Examination of other indices} +Unlike the core index $q$ and the intensity of implication, which +measures quality through probability (see definition 2.3), the other +most common indices are intended to be direct measures of quality. +We will examine their respective sensitivities to changes in the +parameters used to define these indices. +We keep the ratings adopted in paragraph 2.2 and select indices that +are recalled in~\cite{Grasm},~\cite{Lencaa} and~\cite{Grast2}. + +\subsubsection{The Loevinger Index} + +It is an "ancestor" of the indices of +implication~\cite{Loevinger}. This index, rated $H(a,b)$, varies from +1 to $-\infty$. It is defined by: $H(a,b) =1-\frac{n n_{a \wedge + b}}{n_a n_b}$. Its partial derivative with respect to the variable number of counter-examples is therefore: +$$\frac{\partial H}{\partial n_{a \wedge \overline{b}}}=-\frac{n}{n_a n_b}$$ +Thus the implication index is always decreasing with $n_{a \wedge + \overline{b}}$. If it is "close" to 1, implication is "almost" +satisfied. But this index has the disadvantage, not referring to a +probability scale, of not providing a probability threshold and being +invariant in any dilation of $E$, $A$, $B$ and $A \cap \overline{B}$. + + +\subsubsection{The Lift Index} + +It is expressed by: $l =\frac{n n_{a \wedge b}}{n_a n_b}$. +This expression, linear with respect to the examples, can still be +written to highlight the number of counter-examples: +$$l =\frac{n (n_a - n_{a \wedge \overline{b}})}{n_a n_b}$$ +To study the sensitivity of the $l$ to parameter variations, we use: +$$\frac{\partial l}{\partial n_{a \wedge \overline{b}} } = +-\frac{1}{n_a n_b}$$ +Thus, the variation of the Lift index is independent of the variation +of the number of counter-examples. +It is a constant that depends only on variations in the occurrences of $a$ and $b$. Therefore, $l$ decreases when the number of counter-examples increases, which semantically is acceptable, but the rate of decrease does not depend on the rate of growth of $n_{a \wedge \overline{b}}$. + +\subsubsection{Confidence} + +This index is the best known and most widely used thanks to the sound +box available in an Anglo-Saxon publication~\cite{Agrawal}. +It is at the origin of several other commonly used indices which are only variants satisfying this or that semantic requirement... Moreover, it is simple and can be interpreted easily and immediately. +$$c=\frac{n_{a \wedge b}}{n_a} = 1-\frac{n_{a \wedge \overline{b}}}{n_a}$$ + +The first form, linear with respect to the examples, independent of +$n_b$, is interpreted as a conditional frequency of the examples of +$b$ when $a$ is known. +The sensitivity of this index to variations in the occurrence of +counter-examples is read through the partial derivative: +$$\frac{\partial c}{\partial n_{a \wedge \overline{b}} } = +-\frac{1}{n_a }$$ + + +Consequently, confidence increases when $n_{a \wedge \overline{b}}$ +decreases, which is semantically acceptable, but the rate of variation +is constant, independent of the rate of decrease of this number, of +the variations of $n$ and $n_b$. +This property seems not to satisfy intuition. +The gradient of $c$ is expressed only in relation to $n_{a \wedge + \overline{b}}$ and $n_a$: $\displaystyle \binom{ -\frac{1}{n_a}}{\frac{n_{a \wedge b}}{n_a^2}}$ + +This may also appear to be a restriction on the role of parameters in +expressing the sensitivity of the index. + +\section{Gradient field, implicative field} +We highlight here the existence of fields generated by the variables +of the corpus. + +\subsection{Existence of a gradient field} +Like our Newtonian physical space, where a gravitational field emitted +by each material object acts, we can consider that it is the same +around each variable. +For example, the variable $a$ generates a scalar field whose value in +$b$ is maximum and equal to the intensity of implication or the +implicition index $q(a,\overline{b})$. +Its action spreads in V according to differential laws as J.M. Leblond +says, in~\cite{Leblond} p.242. + +Let us consider the space $E$ of dimension 4 where the coordinates of +the points $M$ are the parameters relative to the binary variables $a$ +and $b$, i.e. ($n$, $n_a$, $n_b$, $n_{a\wedge \overline{b}}$). $q(a,\overline{b})$ is the realization of a scalar field, as an application of $\mathbb{R}^4$ in $\mathbb{R}$ (immersion of $\mathbb{N}^4$ in $\mathbb{R}^4$). +For the grad vector $q$ of components the partial derivatives of $q$ +with respect to variables $n$, $n_a$, $n_b$, $n_{a\wedge + \overline{b}}$ to define a gradient field - a particular vector +field that we will also call implicit field - it must respect the +Schwartz criterion of an exact total differential, i.e.: + +$$\frac{\partial}{\partial n_{a\wedge \overline{b}}}\left( +\frac{\partial q}{\partial n_b} \right) =\frac{\partial}{\partial n_b}\left( +\frac{\partial q}{\partial n_{a\wedge \overline{b}}} \right) $$ +and the same for the other variables taken in pairs. However, we have, +through the formulas (\ref{eq2.3}) and (\ref{eq2.4}) + +$$ \frac{\partial}{\partial n_{a \wedge b}} \left( \frac{\partial q}{\partial n_b} \right) = \frac{1}{2} \left( \frac{n_a}{n}\right)^{-\frac{1}{2}} \left( \frac{n_{\overline{b}}}{n}\right)^{-\frac{3}{2}} = \frac{\partial}{\partial n_b}\left( +\frac{\partial q}{\partial n_{a\wedge \overline{b}}} \right)$$ + +Thus, to the vector field C = ($n$, $n_a$, $n_b$, $n_{\overline{b}}$) of $E$, the nature of which we will specify, corresponds a gradient field $G$ which is said to be derived from the {\bf potential} $q$. +The gradient grad $q$ is therefore the vector that represents the spatial variation of the field intensity. +It is directed from low field values to higher values. By following the gradient at each point, we follow the increase in the intensity of the field's implication in space and, in a way, the speed with which it changes as a result of the variation of one or more parameters. + +For example, if we set 3 of the parameters $n$, $n_a$, $n_b$, $n_{\overline{b}}$ given by the realization of the couple ($a$, $b$), the gradient is a vector whose direction indicates the growth or decrease of $q$, therefore the decrease or increase of $|q|$ and, as a consequence of $\varphi$ the variations of the 4th parameter. +We have indicated this above by interpreting formula (\ref{eq2.5}). + + +\subsection{Level or equipotential lines} +An equipotential (or level) line or surface in the $C$ field is a curve of $E$ along which or on which a variable point $M$ maintains the same value of the potential $q$ (e.g. isothermal lines on the globe or level lines on an IGN map). + +The equation of this surface\footnote{In differential geometry, it seems that this surface is a (quasi) differentiable variety on board, compact, homeomorphic with closed pavement of the intervals of variation of the 4 parameters. Note that the point whose component $n_b$ is equal to $n$ (therefore = 0) is a singular point ( "catastrophic" in René Thom's sense) of the surface and $q$, the potential, is not differentiable at this point. Everywhere else, the surface is distinguishable, the points are all regular. If time, for example, parameters the observations of the process of which ($n$, $n_a$, $n_b$, $n_{\overline{b}}$) is a realization, at each instant corresponds a morphological fiber of the process represented by such a surface in space-time.} is, of course: +$$ q(a,\overline{b}) - \frac{n_{a \wedge \overline{b}}- + \frac{n_a.n_{\overline{b}}}{n}}{\sqrt{\frac{n_a.n_{\overline{b}}}{n}}} = 0$$ + + +Therefore, on such a curve, the scalar product $grad~ q. dM$ is zero. +This is interpreted as indicating the orthogonality of the gradient with the tangent or hyperplane tangent to the curve, i.e. with the equipotential line or surface. +In a kinematic interpretation of our problem, the velocity of $M$'s path on the equipotential surface is orthogonal to the gradient in $M$. + +As an illustration in Figure~\ref{chap2fig2}, for a potential $F$ depending on only 2 variables, the figure below shows the orthogonal direction of the gradient with respect to the different equipotential surfaces along which the potential $F$ does not vary but passes from $F=7$ to $F= 10$. + +\begin{figure}[htbp] + \centering +\includegraphics[scale=1]{chap2fig2} + \caption{Illustration of potential of 2 variables} +\label{chap2fig2} % Give a unique label +\end{figure} + +It is possible in the case of the potential $q$, to build equipotential surfaces as above (two-dimensional for ease of representation). +It is understandable that the more intense the field is, the tighter the surfaces are. For a given value of $q$, in this case, 3 variables are set, for example $n$, $n_a$, $n_b$ and a value of $q$ compatible with the field constraints. Either: $n = 104$; $n_a = 1600 \leq nb = 3600$ and $q = -2$ or $|q| = 2$. We then find $n_{\overline{b}}= 528$ using formula~(\ref{eq2.1}). +But the points ($10^4$, $1600$, $5100$, $5100$, $728$) and ($100$, $25$, $64$, $3$) also belong to this surface and the same equipotential curve. +The point ($104$, $1600$, $3600$, $3600$, $928$) belongs to the equipotential curve $q=-3$). In fact, on this entire surface, we obtain a kind of homeostasis of the intensity of implication. + +The expression of the function $q$ of the variable shows that it is convex. +This property proves that the segment of points $t.M_1 + (1-t).M_2$, for $t \in [0,1]$ which connects two points $M_1$ and $M_2$ of the same equipotential line is entirely contained in its convexity. +The figure below shows two adjacent equipotential surfaces $\sum_1$ and $\sum_2$ in the implicit field corresponding to two values of the potential $q_1$ and $q_2$. +At point $M_1$ the scalar field therefore takes the value $q_1$. $M_2$ is the intersection of the normal from $M_1$ with $\sum_2$. Given the direction of the normal vector $\vec{n}$ the difference $\delta = q2 - q1$, variation of the field when we go from $\sum_1$ to $\sum_2$ is then equal to the opposite of the norm of the gradient from $q$ to $M_1$ is $\frac{\partial q}{\partial n}$, if $n_a$, $n_b$ and $n_{a \wedge \overline{b}}$ are fixed. + +\begin{figure}[htbp] + \centering +\includegraphics[scale=1]{chap2fig3} + \caption{Illustration of equipotential surfaces} +\label{chap2fig3} % Give a unique label +\end{figure} + +Thus, the space $E$ can be laminated by equipotential surfaces corresponding to successive values of $q$ relative to the cardinals ($n$, $n_a$, $n_b$, $n_{a \wedge \overline{b}}$) which would be varied. +This situation corresponds to the one envisaged in the SIA modeling. +Fixing $n$, $n_a$ and $n_b$, we consider the random sets $X$ and $Y$ of the same cardinals as $A(n_a)$ and $B(n_b)$ and whose cardinal follows a Poisson's law or a binomial law, according to the choice of the model. +The different gradient fields, real "lines of force", associated with them are orthogonal to the surfaces defined by the corresponding values of $Q$. +This reminds us, in the theoretical framework of potential, of the premonitory metaphor of "implicit flow" that we expressed in~\cite{Grase} and that we will discuss again in Chapter 14 of the book. +Behind this notion we can imagine a transport of information of variable intensity in a causal universe. +We illustrate this metaphor with the study of the properties of the two-layer implicit cone (see §2.8). +Moreover and intuitively, the implication $a\Rightarrow b$ is of as good quality as the equipotential surface $C$ of the contingency covers random equipotential surfaces depending on the random variable. +Let us recall the relationship that unites the potential q with the intensity: +$$\varphi(a,b) =\frac{1}{\sqrt{2\pi}}\int_{q(a,\overline{b})}^{\infty}e^{-\frac{t^2}{2}} dt$$ + +\noindent {\bf remark 1}\\ +It can be seen that the intensity is also invariant on any equipotential surface of its own variations. +The surface portions generated by $q$ and by $\varphi$ are even in one-to-one correspondence. +In intuitive terms, we can say that when one "swells" the other "deflates".\\ + +\noindent {\bf remark 2}\\ +Let us note once again a particularity of the intensity of implication. +While the surfaces generated by the variations of the 4 parameters of the data are not invariant by the same dilation of the parameters, those associated with the indices cited in §2.4 are invariant and have the same undifferentiated geometric shape. + +\section{Implication-inclusion} +\subsection{Foundational and problematic situation} +Three reasons led us to improve the model formalized by the intensity of involvement: +\begin{itemize} +\item when the size of the samples processed, and in particular that of $E$, increases (by around a thousand and more), the intensity $\varphi(a,b)$ no longer tends to be sufficiently discriminating because its values can be very close to 1, while the inclusion whose quality it seeks to model is far from being satisfied (phenomenon reported in~\cite{Bodina} which deals with large student populations through international surveys); +\item the previous quasi-implication model essentially uses the measure of the strength of rule $a \Rightarrow b$. + However, taking into account a concomitance of $\neg b \Rightarrow \neg a$ (contraposed of implication) is useful or even essential to reinforce the affirmation of a good quality of the quasi-implicative, possibly quasi-causal, relationship of $a$ over $b$\footnote{This phenomenon is reported by Y. Kodratoff in~\cite{Kodratoff}.}. + At the same time, it could make it possible to correct the difficulty mentioned above (if $A$ and $B$ are small compared to $E$, their complementary will be important and vice versa); +\item the overcoming of Hempel's paradox (see Appendix 3 of this chapter). + \end{itemize} + +\subsection{An inclusion index} + +The solution\footnote{J. Blanchard provides in~\cite{Blanchardb} an answer to this problem by measuring the "equilibrium gap".} we provide uses both the intensity of implication and another index that reflects the asymmetry between situations $S_1 = (a \wedge b)$ and $S_1' = (a \wedge \neg b)$, (resp. $S2 = (\neg a \wedge \neg b)$ and $S_2' = (a \wedge \neg b)$) in favour of the first named. +The relative weakness of instances that contradict the rule and its counterpart is therefore fundamental. +Moreover, the number of counter-examples $n_{a \wedge \overline{b}}$ to $a\ Rightarrow b$ is the one to the contraposed one. +To account for the uncertainty associated with a possible bet of belonging to one of the two situations ($S_1$ or $S_1'$, (resp. $S_2$ or $S_2'$)), we therefore refer to Shannon's concept of entropy~\cite{Shannon}: +$$H(b\mid a) = - \frac{n_{a\wedge b}}{n_a}log_2 \frac{n_{a\wedge b}}{n_a} - \frac{n_{a\wedge \overline{b}}}{n_a}log_2 \frac{n_{a\wedge \overline{b}}}{n_a}$$ +is the conditional entropy relating to boxes $(a \wedge b)$ and $(a \wedge \neg b)$ when $a$ is realized + +$$H(\overline{a}\mid \overline{b}) = - \frac{n_{a\wedge \overline{b}}}{n_{\overline{b}}}log_2 \frac{n_{a\wedge \overline{b}}}{n_{\overline{b}}} - \frac{n_{\overline{a} \wedge \overline{b}}}{n_{\overline{b}}}log_2 \frac{n_{\overline{a} \wedge \overline{b}}}{n_{\overline{b}}}$$ + +is the conditional entropy relative to the boxes $(\neg a \wedge \neg b)$ and $(a \wedge \neg b)$ when not $b$ is realized. + +These entropies, with values in $[0,1]$, should therefore be simultaneously weak and therefore the asymmetries between situations $S_1$ and $S_1'$ (resp. $S_2$ and $S_2'$) should be simultaneously strong if one wishes to have a good criterion for including $A$ in $B$. +Indeed, entropies represent the average uncertainty of experiments that consist in observing whether b is performed (or not a is performed) when a (or not b) is observed. The complement to 1 of this uncertainty therefore represents the average information collected by performing these experiments. The more important this information is, the stronger is the guarantee of the quality of the involvement and its counterpart. We must now adapt this entropic numerical criterion to the model expected in the different cardinal situations. +For the model to have the expected meaning, it must satisfy, in our opinion, the following epistemological constraints: + +\begin{enumerate} +\item It shall integrate the entropy values and, to contrast them, for example, integrate these values into the square. +\item As this square varies from 0 to 1, in order to denote the imbalance and therefore the inclusion, in order to oppose entropy, the value retained will be the complement to 1 of its square as long as the number of counter-examples is less than half of the observations of a (resp. non b). + Beyond these values, as the implications no longer have an inclusive meaning, the criterion will be assigned the value 0. +\item In order to take into account the two information specific to $a\Rightarrow b$ and $\neg b \Rightarrow \neg a$, the product will report on the simultaneous quality of the values retained. +The product has the property of cancelling itself as soon as one of its terms is cancelled, i.e. as soon as this quality is erased. +\item Finally, since the product has a dimension 4 with respect to entropy, its fourth root will be of the same dimension. +\end{enumerate} + +Let $\alpha=\frac{n_a}{n}$ be the frequency of a and $\overline{b}=\frac{n_{\overline{b}}}{n}$ be the frequency of non b. +Let $t=\frac{n_{a \wedge \overline{b}}}{n}$ be the frequency of counter-examples, the two significant terms of the respective qualities of involvement and its counterpart are: + +\begin{eqnarray*} + h_1(t) = H(b\mid a) = - (1-\frac{t}{\alpha}) log_2 (1-\frac{t}{\alpha}) - \frac{t}{\alpha} log_2 \frac{t}{\alpha} & \mbox{ if }t \in [0,\frac{\alpha}{2}[\\ + h_1(t) = 1 & \mbox{ if }t \in [\frac{\alpha}{2},\alpha]\\ + h_2(t)= H(\overline{a}\mid \overline{b}) = - (1-\frac{t}{\overline{\beta}}) log_2 (1-\frac{t}{\overline{\beta}}) - \frac{t}{\overline{b}} log_2 \frac{t}{\overline{b}} & \mbox{ if }t \in [0,\frac{\overline{\beta}}{2}[\\ + h_2(t)= 1 & \mbox{ if }t \in [\frac{\overline{\beta}}{2},\overline{\beta}] +\end{eqnarray*} +Hence the definition for determining the entropic criterion: +\definition: The inclusion index of A, support of a, in B, support of b, is the number: +$$i(a,b) = \left[ (1-h_1^2(t)) (1-h_2^2(t))) \right]^{\frac{1}{4}}$$ + +which integrates the information provided by the realization of a small number of counter-examples, on the one hand to the rule $a \Rightarrow b$ and, on the other hand, to the rule $\neg b \Rightarrow \neg a$. + +\subsection{The implication-inclusion index} + +The intensity of implication-inclusion (or entropic intensity), a new measure of inductive quality, is the number: + +$$\psi(a,b)= \left[ i(a,b).\varphi(a,b) \right]^{\frac{1}{2}}$$ +which integrates both statistical surprise and inclusive quality. + +The function $\psi$ of the variable $t$ admits a representation that has the shape indicated in Figure~\ref{chap2fig4}, for $n_a$ and $n_b$ fixed. +Note in this figure the difference in the behaviour of the function with respect to the conditional probability $P(B\mid A)$, a fundamental index of other rule measurement models, for example in Agrawal. +In addition to its linear, and therefore not very nuanced nature, this probability leads to a measure that decreases too quickly from the first counter-examples and then resists too long when they become important. + + +\begin{figure}[htbp] + \centering +\includegraphics[scale=0.5]{chap2fig4.png} +\caption{Example of implication-inclusion.} + +\label{chap2fig4} +\end{figure} + +In Figure~\ref{chap2fig4}, it can be seen that this representation of the continuous function of $t$ reflects the expected properties of the inclusion criterion: +\begin{itemize} +\item ``Slow reaction'' to the first counter-examples (noise resistance), +\item ``acceleration'' of the rejection of inclusion close to the balance i.e. $\frac{n_a}{2n}$, +\item rejection beyond $\frac{n_a}{2n}$, the intensity of implication $\varphi(a,b)$ did not ensure it. +\end{itemize} + +\noindent Example 1\\ +\begin{tabular}{|c|c|c|c|}\hline + & $b$ & $\overline{b}$ & margin\\ \hline + $a$ & 200 & 400& 600 \\ \hline + $\overline{a}$ & 600 & 2800& 3400 \\ \hline + margin & 800 & 3200& 4000 \\ \hline +\end{tabular} +\\ +\\ +In Example 1, implication intensity is $\varphi(a,b)=0.9999$ (with $q(a,\overline{b})=-3.65$). + The entropic values of the experiment are $h_1=h_2=0$. + The value of the moderator coefficient is therefore $i(a,b)=0$. + Hence, $\psi(a,b)=0$ whereas $P(B\mid A)=0.33$. +Thus, the "entropic" functions "moderate" the intensity of implication in this case where inclusion is poor. +\\ +\\ +\noindent Example 2\\ + \begin{tabular}{|c|c|c|c|}\hline + & $b$ & $\overline{b}$ & margin\\ \hline + $a$ & 400 & 200& 600 \\ \hline + $\overline{a}$ & 1000 & 2400& 3400 \\ \hline + margin & 1400 & 2600& 4000 \\ \hline + \end{tabular} + \\ + \\ + In Example 2, intensity of implication is 1 (for $q(a,\overline{b}) = - 8.43$). + The entropic values of the experiment are $h_1 = 0.918$ and $h_2 = 0.391$. + The value of the moderator coefficient is therefore $i(a,b) = 0.6035$. + As a result $\psi(a,b) = 0.777$ whereas $P(B \mid A) = 0.6666$. + \\ + \\ +{\bf remark} + \noindent The correspondence between $\varphi(a,b)$ and $\psi(a,b)$ is not monotonous as shown in the following example: + +\begin{tabular}{|c|c|c|c|}\hline + & $b$ & $\overline{b}$ & margin\\ \hline + $a$ & 40 & 20& 60 \\ \hline + $\overline{a}$ & 60 & 280& 340 \\ \hline + margin & 100 & 300& 400 \\ \hline +\end{tabular} +\\ +Thus, while $\varphi(a,b)$ decreased from the 1st to the 2nd example, $i(a,b)$ increased as well as $\psi(a,b)$. On the other hand, the opposite situation is the most frequent. +Note that in both cases, the conditional probability does not change. +\\ +\\ +{\bf remark} +\noindent We refer to~\cite{Lencaa} for a very detailed comparative study of association indices for binary variables. +In particular, the intensities of classical and entropic (inclusion) implication presented in this article are compared with other indices according to a "user" entry. + +\section{Implication graph} +\subsection{Problematic} + +At the end of the calculations of the intensities of implication in both the classical and entropic models, we have a table $p \times p$ that crosses the $p$ variables with each other, whatever their nature, and whose elements are the values of these intensities of implication, numbers of the interval $[0,~1]$. +It must be noted that the underlying structure of all these variables is far from explicit and remains largely unimportant. +The user remains blind to such a square table of size $p^2$. +It cannot simultaneously embrace the possible multiple sequences of rules that underlie the overall structure of all $p$ variables. +In order to facilitate a clearer extraction of the rules and to examine their structure, we have associated to this table, and for a given intensity threshold, an oriented graph, weighted by the intensities of implication, without a cycle whose complexity of representation the user can control by setting himself the threshold for taking into account the implicit quality of the rules. +Each arc in this graph represents a rule: if $n_a < n_b$, the arc $a \rightarrow b$ represents the rule $a \Rightarrow b$ ; if $n_a = n_b$, then the arc $a \leftrightarrow b$ will represent the double rule $a \Leftrightarrow b$, in other words, the equivalence between these two variables. +By varying the threshold of intensity of implication, it is obvious that the number of arcs varies in the opposite direction: for a threshold set at $0.95$, the number of arcs is less than or equal to those that would constitute the graph at threshold $0.90$. We will discuss this further below. + +\subsection{Algorithm} + +The relationship defined by statistical implication, if it is reflexive and not symmetrical, is obviously not transitive, as is induction and, on the contrary, deduction. +However, we want it to model the partial relationship between two variables (the successes in our initial example). +By convention, if $a \Rightarrow b$ and $b \Rightarrow c$, we will accept the transitive closure $a \Rightarrow c$ only if $\psi(a,c) \geq 0.5$, i.e. if the implicit relationship of $a$ to $c$ is better than neutrality by emphasizing the dependence between $a$ and $c$. + + +{\bf VERIFIER PHI PSI}\\ +\\ +{\bf Proposal:} By convention, if $a \Rightarrow b$ and $b \Rightarrow c$, there is a transitive closure $a \Rightarrow c$ if and only if $\psi(a,c) \geq 0.5$, i.e. if the implicit relationship of $a$ over $c$, which reflects a certain dependence between $a$ and $c$, is better than its refutation. +Note that for any pair of variables $(x;~ y)$, the arc $x \rightarrow y$ is weighted by the intensity of involvement (x,y). +\\ +Let us take a formal example by assuming that between the 5 variables $a$, $b$, $c$, $d$, and $e$ exist, at the threshold above $0.5$, the following rules: $c \Rightarrow a$, $c \Rightarrow e$, $c \Rightarrow b$, $d \Rightarrow a$, $d \Rightarrow e$, $a \Rightarrow b$ and $a \Rightarrow e$. + +This set of numerical and graphical relationships can then be translated into the following table and graph: + +\begin{tabular}{|C{0.5cm}|c|c|c|c|c|}\hline +\hspace{-0.5cm}\turn{45}{$\Rightarrow$} & $a$ & $b$ & $c$ & $d$ & $e$\\ \hline +$a$ & & 0.97& & & 0.73 \\ \hline +$b$ & & & & & \\ \hline + $c$ & 0.82 & 0.975& & & 0.82 \\ \hline + $d$ & 0.78 & & & & 0.92 \\ \hline + $e$ & & & & & \\ \hline +\end{tabular} + +\begin{figure}[htbp] + \centering +\includegraphics[scale=1]{chap2fig5.png} +\caption{Implication graph corresponding to the previous example.} + +\label{chap2fig5} +\end{figure}