From 66bdc377c44bdcd2c92cc942be0a3035dacfd4ee Mon Sep 17 00:00:00 2001
From: grr <grr@lo2.org>
Date: Fri, 3 May 2024 09:13:46 -0400
Subject: like, a bunch of stuff
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+\chapter{The Logic of Admissible Contradictions (Work in Progress)}
+
+\section{Chapter III. A Provisional Axiomatic Treatment}
+
+
+In the first and second chapters, we developed our intuitions
+concerning perceptions of the logically impossible in as much detail as we
+could. We decided, on intuitive grounds, which contradictions were
+admissible and which were not. As we proceeded, it began to appear that the
+results suggested by intuition were cases of a few general principles. In this
+chapter, we will adopt these principles as postulates. The restatement of our
+theory does not render the preceding chapters unnecessary. Only by
+beginning with an exhaustive, intuitive discussion of perceptual illusions
+could we convey the substance underlying the notations which we call
+admissble contradictions, and motivate the unusual collection of postulates
+which we will adopt.
+
+All properties will be thought of as "parameters," such as time,
+location, color, density, acidity, etc. Different parameters will be represented
+by the letters x, y, z, .... Different values of one parameter, say x, will be
+represented by $x_1$, $x_2$, .... Each parameter has a domain, the set of all values
+it can assume. An ensembie ($x_0$, $y_0$, $z_0$, ...) will stand for the single possible
+phenomenon which has x-value $x_0$, y-value $y_0$, etc. Several remarks are in
+order. My ensembles are a highly refined version of Rudolph Carnap's
+intensions or intension sets (sets of all possible entities having a given
+property). The number of parameters, or properties, must be supposed to be
+indefinitely large. By giving a possible phenomenon fixed values for every
+parameter, I assure that there will be only one such possible phenomenon. In
+other words, my intension sets are all singletons. Another point is that if we
+specify some of the parameters and specify their ranges, we limit the
+phenomena which can be represented by our "ensembles." If our first
+parameter is time and its range is $R$, and our second parameter is spatial
+location and its range is $R^2$, then we are limited to phenomena which are
+point phenomena in space and time. If we have a parameter for speed of
+motion, the motion will have to be infinitesimal. We cannot have a
+parameter for weight at all; we can only have one for density. The physicist
+encounters similar conceptual problems, and does noi find them
+insurmountable.
+
+Let ($x_1$, $y$, $z$, ...), ($x_2$, $y$, $z$, ...), etc. stand for possible phenomena
+which all differ from each other in respect to parameter x but are identical in
+respect to every other parameter $y$, $z$, ... . (If the ensembles were intension
+sets, they would be disjoint precisely because $x$ takes a different value in
+each.) A "simple contradiction family" of ensembles is the family [($x_1$,$y$,$z$,
+...), ($x_2$, $y$, $z$, ...), ...]. The family may have any number of ensembles. It
+actually represents many families, because $y$, $z$, ... are allowed to vary; but
+each of these parameters must assume the same value in all ensembles in any
+one family. $x$, on the other hand, takes different values in each ensemble in
+any one family, values which may be fixed. A parameter which has the same
+value throughout any one family will be referred to as a consistency
+parameter. A parameter which has a different value in each ensemble in a
+given family will be referred to as a contradiction parameter.
+"Contradiction" will be shortened to "con." A simple con family is then a
+family with one con parameter. The consistency parameters may be dropped
+from the notation, but the reader must remember that they are implicitly
+present, and must remember how they function.
+
+A con parameter, instead of being fixed in every ensemble, may be
+restricted to a different subset of its domain in every ensemble. The subsets
+must be mutually disjoint for the con family to be well-defined. The con
+family then represents many families in another dimension, because it
+represents every family which can be formed by choosing a con parameter
+value from the first subset, one from the second subset, etc.
+
+Con families can be defined which have more than one con parameter,
+i.e. more than one parameter satisfying all the conditions we put on x. Such
+con families are not "simple." Let the cardinality of a con family be
+indicated by a number prefixed to "family," and let the number of con
+parameters be indicated by a number prefixed to "con." Remembering that
+consistency parameters are understood, a 2-con $\infty$-family would appear as
+[($x_1$, $y_1$). ($x_2$, $y_2$), ...].
+
+A "contradiction" or "$\varphi$-object" is not explicitly defined, but it is
+notated by putting "$\varphi$" in front of a con family. The characteristics of $\varphi$-objects,
+or cons, are established by introducing additional postulates in the
+theory.
+
+In this theory, every con is either "admissible" or "not admissible."
+"Admissible" will be shortened to "am." The initial amcons of the theory
+are introduced by postulate. Essentially, what is postulated is that cons with
+a certain con parameter are am. (The cons directly postulated to be am are
+on 1-con families.) However, the postulate will specify other requirements for
+admissibility besides having the given con parameter. The requisite
+cardinality of the con family will be specified. Also, the subsets will be
+specified to which the con parameter must be restricted in each ensemble in
+the con. A con must satisfy all postulated requirements before it is admitted
+by the postulate.
+
+The task of the theory is to determine whether the admissibility of the
+cons postulated to be am implies the admissibility of any other cons. The
+method we have developed for solving such problems will be expressed as a
+collection of posiulates for our theory.
+
+\postulate{1} Given $\varphi[(x\in A),(x\in B),\ldots]$ am, where $x\in A$, $x\in B$, ... are the
+restrictions on the con parameter, and given $A_1\subset A$, $B_1\subset B$, ..., where $A_1,B_1,...\neq\emptyset$, then
+$\varphi[(x\in A_1),(x\in B_1),...]$ is am. This postulate is obviously
+equivalent to the postulate that $\varphi[(x\in A\cap C),(x\in B\cap C),...]$ is am, where $C$ is
+a subset of $x$'s domain end the intersections are non-empty. (Proof: Choose
+$C=A_1\cup B_1\cup\ldots$ .)
+
+\postulate{2} If $x$ and $y$ are simple amcon parameters, then a con with con
+parameters $x$ and $y$ is am if it satisfies the postulated requirements
+concerning amcons on $x$ and the postulated requirements concerning amcons
+on $y$.
+
+The effect of all our assumptions up to now is to make parameters
+totally independent. They do not interact with each other at all.
+
+We will now introduce some specific amcons by postulate. If $s$ is speed,
+consideration of the waterfall illusion suggests that we postulate
+$\varphi[(s>O),(s=O)]$ to be am. (But with this postulate, we have come a long way from
+the literary description of the waterfall illusion!) Note the implicit
+requirements that the con family must be a 2-family, and that $s$ must be
+selected from $[O]$ in one ensemble and from ${s:s>O}$ in the other ensemble.
+
+If $t$ is time, $t\in R$, consideration of the phrase "b years ago," which is an
+amcon in the natural language, suggests that we postulate $\varphi[(t):a-b\leq t\leq v-b \&a\leq v]$ to be am,
+where $a$ is a fixed time expressed in years A.D., $b$ is a fixed
+number of years, and $v$ is a variable---the time of the present instant in years
+A.D. The implicit requirements are that the con family must have the
+cardinality of the continuum, and that every value of $t$ from $a-b$ to $v-b$ must
+appear in an ensemble, where $v$ is a variable. Ensembles are thus continually
+added to the con family. Note that there is the non-trivial possibility of using
+this postulate more than once. We could admit a con for $a=1964$, $b=\sfrac{1}{2}$
+then admit another for $a=1963$, $b=2$, and admit still another for $a=1963$,
+$b=1$; etc.
+
+Let $p$ be spatial location, $p\in R^2$. Let $P_i$ be a non-empty, bounded,
+connected subset of $R^2$. Restriction subsets will be selected from the $P_i$.
+Specifically, let $P_1\cap P_2=\emptyset$. Consideration of a certain dreamed illusion
+suggests that we admit $\varphi[(p\in P_1),(p\in P_2)]$. The implicit requirements are
+obvious. But in this case, there are more requirements in the postulate of
+admissibility. May we apply the postulate twice? May we admit first
+$\varphi[(p\in P_1),(p\in P_2)]$ and then $\varphi[(p\in P_3),(p\in P_4)]$, where $P_3$ and $P_4$ are arbitrary
+$P_i$'s different from $P_1$ and $P_2$? The answer is no. We may admit
+$\varphi[(p\in P_1),(p\in P_2)]$ for arbitrary $P_1$ and $P_2$, $P_1\cap P_2=\emptyset$, but having made this "initial
+choice," the postulate cannot be reused for arbitrary $P_3$ and $P_4$. A second
+con $\varphi[(p\in P_3),(p\in P_4)]$, $P_3\cap P_4=\emptyset$, may be postulated to be am only if
+$P_1\cup P_3$,$P_2\cup P_3$,$P_1\cup P_4$, and $P_2\cup P_4$ are not connected. In other words, you
+may postulate many cons of the form $\varphi[(p\in P_i),(p\in P_j)]$ to be am, but
+your first choice strongly circumscribes your second choice, etc.
+
+We will now consider certain results in the logic of amcons which were
+established by extensive elucidation of our intuitions. The issue is whether
+our present axiomization produces the same results. We will express the
+results in our latest notation as far as possible. Two more definitions are
+necessary. The parameter $\theta$ is the angle of motion of an infinitesimally
+moving phenomenon, measured in degrees with respect to some chosen axis.
+Then, recalling the set $P_1$, choose $P_5$ and $P_6$ so that $P_1=P_5\cup P_6$ and
+$P_5\cap P_6=\emptyset$.
+
+The results by which we will judge our axiomization are as follows.
+
+\begin{enumerate} % TODO with colons?
+
+ \item $\varphi[S, C_1\cup C_2]$ can be inferred to be am.
+
+Our present notation cannot express this result, because it does not
+distinguish between different types of uniform motion throughout a finite
+region, \ie the types $M$, $C_1$, $C_2$, $D_1$, and $D_2$. Instead, we have infinitesimal
+motion, which is involved in all the latter types of motion. Questions such as
+"whether the admissibility of $\varphi[M,S]$ implies the admissibility of $\varphi[C_1,S]$"
+drop out. The reason for the omission in the present theory is our choice of
+parameters and domains, which we discussed earlier. Our present version is
+thus not exhaustive. However, the deficiency is not intrinsic to our method;
+and it does not represent any outright falsification of our intuitions. Thus,
+we pass over the deficiency.
+
+\item $\varphi[(p\in P_1,s_0),(p\in P_2,S_0)]$ and other such cons can be inferred to be am.
+With our new, powerful approach, this result is trivial. It is guaranteed by
+what we said about consistency parameters.
+
+\item There is no way to infer that $\varphi[C_1,C_2]$ is am; and no way to infer that
+$\varphi[(45^\circ,s_0\greater O),(60^\circ,s=s_0)]$ is am.
+
+The first part of the result drops out. The second part is trivial with our new
+method as long as we do not postulate that cons on $\theta$ are am.
+
+\item $\varphi[(p\in P_2),(p\in P_5)]$ can be inferred to be am.
+
+Yes, by Postulate 1.
+
+\item $\varphi[(s>O, p\in P_1),(s=O, p\in P_2)]$ and $\varphi[(s>O, p\in P_2),(s=O, p\in P_1)]$ can
+be inferred to be am.
+
+Yes, by Postulate 2. These two amcons are distinct. The question of whether
+they should be considered equivalent is closely related to the degree to
+which con parameters are independent of each other.
+
+\item There is no way to infer that $\varphi[(p\in P_5),(p\in P_6)]$ or $\varphi[(p\in P_1),(p\in P_3)]$
+is am. Our special requirement in the postulate of admissibility for
+$\varphi[(p\in P_1),(p\in P_2)]$ guarantees this result.
+\end{enumerate}
+
+The reason for desiring this last result requires some discussion. In
+heuristic terms, we wish to avoid admitting both location in New York in
+Greensboro and location in Manhattan and Brooklyn. We also wish to avoid
+admitting location in New York in Greensboro and location in New York in
+Boston. If we admitted either of these combinations, then the intuitive
+rationale of the notions would indicate that we had admitted triple location.
+While we have a dreamed illusion which justifies the concept of double
+location, we have no intuitive justification whatever for the concept of triple
+location. It must be clear that admission of either of the combinations
+mentioned would not imply the admissibility of a con on a 3-family with
+con parameter p by the postulates of our theory. Our theory is formally safe
+from this implication. However, the intuitive meaning of either combination
+would make them proxies for the con on the 3-family.
+
+A closely related consideration is that in the preceding chapter, it
+appeared that the admission of $\varphi[(p\in P_1),(p\in P_2)]$ and $\varphi[(p\in P_5),(p\in P_6)]$
+would tend to require the admission of the object $\varphi[(p\in P_2),\varphi[(p\in P_5),(p\in P_6)]]$
+(a Type 1 chain). Further, it this implication held, then by the same
+rationale the admission of $\varphi[(p\in P_1),(p\in P_2)]$ and $\varphi[(s>O,p_0\in P_1),(s=O,p=p_0)]$,
+ both of which are am, would require the admission of the object
+$\varphi[(p\in P_2), \varphi[(s>O,p_0\in P_1),(s=O, p=p_0)]]$.
+We may now say, however,
+that the postulates of our theory emphatically do not require us to accept
+these implications. If there is an intuitively valid notion underlying the chain
+on s and p, it reduces to the amcons introduced in result 5. As for the chain
+on p alone, we repeat that simultaneous admission of the two cons
+mentioned would tend to justify some triple location concept. However, we
+do not have to recognize that concept as being the chain. It seems that our
+present approach allows us to forget about chains for now.
+
+Our conclusion is that the formal approach of this chapter is in good
+agreement with our intuitively established results.
+
+\section*{Note on the overall significance of the logic of amcons:}
+
+When traditional logicians said that something was logically impossible,
+they meant to imply that it was impossible to imagine or visualize. But this
+implication was empirically false. The realm of the logically possible is not
+the entire realm of connotative thought; it is just the realm of normal
+perceptual routines. When the mind is temporarily freed from normal
+perceptual routines---especially in perceptual illusions, but also in dreams and
+even in the use of certain "illogical" natural language phrases---it can imagine
+and visualize the "logically impossible." Every text on perceptual
+psychology mentions this fact, but logicians have never noticed its immense
+significance. The logically impossible is not a blank; it is a whole layer of
+meaning and concepts which can be superimposed on conventional logic, but
+not reduced or assimilated to it. The logician of the future may use a drug or
+some other method to free himself from normal perceptual routines for a
+sustained period of time, so he can freely think the logically impossible. He
+will then perform rigorous deductions and computations in the logic of
+amcons.
+
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