Difference between revisions of "Directory:Jon Awbrey/MathJax Problems"

The next Example is extremely important, and for reasons that reach well beyond the level of propositional calculus as it is ordinarily conceived.  But it's slightly tricky to get all of the details right, so it will be worth taking the trouble to look at it from several different angles and as it appears in diverse frames, genres, or styles of representation.

In discussing this Example, it is useful to observe that the implication relation indicated by the propositional form <math>x \Rightarrow y\!</math> is equivalent to an order relation <math>x \le y\!</math> on the boolean values <math>0, 1 \in \mathbb{B},\!</math> where <math>0\!</math> is taken to be less than <math>1.\!</math>

{| align="center" cellpadding="8" width="90%"

| width="1%" | <big>&bull;</big>

| colspan="3" | '''Example 2.  Transitivity'''

| width="1%" | &nbsp;

| colspan="2" | ''Information Reducing Inference''

| &nbsp;

| &nbsp;

| width="1%" | &nbsp;

| &nbsp;

| &nbsp;

| colspan="2" | ''Information Preserving Inference''

| &nbsp;

| &nbsp;

| &nbsp;

<math>\begin{array}{l}

~ p \le q

~ q \le r

\overline{\underline{~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~}}

~ p \le q \le r

\end{array}</math>

In stating the information-preserving analogue of transitivity, I have taken advantage of a common idiom in the use of order relation symbols, one that represents their logical conjunction by way of a concatenated syntax.  Thus, <math>p \le q \le r\!</math> means <math>p \le q ~\mathrm{and}~ q \le r.\!</math>  The claim that this 3-adic order relation holds among the three propositions <math>p, q, r\!</math> is a stronger claim &mdash; conveys more information &mdash; than the claim that the 2-adic relation <math>p \le r\!</math> holds between the two propositions <math>p\!</math> and <math>r.\!</math>

 

 

{| align="center" border="1" cellpadding="8" cellspacing="0" style="text-align:center; width:90%"

|- style="background:#f0f0ff"

\\[4pt]

f_{175}

\\[4pt]

f_{139}

\end{matrix}</math>

<math>\begin{matrix}

f_{11001111}

\\[4pt]

\\[4pt]

f_{10001011}

\end{matrix}</math>

<math>\begin{matrix}

\\[4pt]

1~0~1~0~1~1~1~1

\\[4pt]

1~0~0~0~1~0~1~1

\end{matrix}</math>

<math>\begin{matrix}

\texttt{(} p \texttt{ (} q \texttt{))}

\texttt{(} q \texttt{ (} r \texttt{))}

\texttt{(} p \texttt{ (} r \texttt{))}

\texttt{(} p \texttt{ (} q \texttt{)) (} q \texttt{ (} r \texttt{))}

Taking up another angle of incidence by way of extra perspective, let us now reflect on the venn diagrams of our four propositions.

{| align="center" cellpadding="6" style="text-align:center"

| <math>f_{207}(p, q, r) ~=~ \texttt{(} p \texttt{ (} q \texttt{))}\!</math>

| <math>f_{187}(p, q, r) ~=~ \texttt{(} q \texttt{ (} r \texttt{))}\!</math>

| <math>f_{175}(p, q, r) ~=~ \texttt{(} p \texttt{ (} r \texttt{))}\!</math>

 

 

By way of general definition, the ''fiber'' of a function <math>f : X \to Y\!</math> at a given value <math>y\!</math> of its co-domain <math>Y\!</math> is the ''antecedent'' (also known as the ''inverse image'' or ''pre-image'') of <math>y\!</math> under <math>f.\!</math> This is a subset, possibly empty, of the domain <math>X,\!</math> notated as <math>f^{-1}(y) \subseteq X.\!</math>

In particular, if <math>f\!</math> is a proposition <math>f : X \to \mathbb{B},\!</math> then the fiber of truth <math>f^{-1}(1)\!</math> is the subset of <math>X\!</math> that is ''indicated'' by the proposition <math>f.\!</math>  Whenever we ''assert'' a proposition <math>f : X \to \mathbb{B},\!</math> we are saying that what it indicates is all that happens to be the case in the relevant universe of discourse <math>X.\!</math>  Because the fiber of truth is used so often in logical contexts, it is convenient to define the more compact notation <math>[| f |] = f^{-1}(1).\!</math>

Using this panoply of notions and notations, we may treat the fiber of truth of each proposition <math>f : \mathbb{B}^3 \to \mathbb{B}\!</math> as if it were a relational data table of the shape <math>\{ (p, q, r) \} \subseteq \mathbb{B}^3,\!</math> where the triples <math>(p, q, r)\!</math> are bit-tuples indicated by the proposition <math>f.\!</math>

 

{| align="center" cellpadding="8" cellspacing="0" style="border-left:1px solid black; border-top:1px solid black; border-right:1px solid black; border-bottom:1px solid black; text-align:center; width:40%"

| style="border-bottom:1px solid black" | <math>q\!</math>

| <math>0\!</math> || <math>0\!</math> || <math>0\!</math>

| <math>0\!</math> || <math>0\!</math> || <math>1\!</math>

| <math>0\!</math> || <math>1\!</math> || <math>0\!</math>

| <math>0\!</math> || <math>1\!</math> || <math>1\!</math>

| <math>1\!</math> || <math>1\!</math> || <math>0\!</math>

| <math>1\!</math> || <math>1\!</math> || <math>1\!</math>

 

 

{| align="center" cellpadding="8" cellspacing="0" style="border-left:1px solid black; border-top:1px solid black; border-right:1px solid black; border-bottom:1px solid black; text-align:center; width:40%"

|+ style="height:30px" | <math>\text{Table 57.} ~~ [| f_{187} |] ~=~ [| q \le r |]\!</math>

| <math>0\!</math> || <math>0\!</math> || <math>0\!</math>

| <math>0\!</math> || <math>0\!</math> || <math>1\!</math>

| <math>0\!</math> || <math>1\!</math> || <math>1\!</math>

| <math>1\!</math> || <math>0\!</math> || <math>0\!</math>

| <math>1\!</math> || <math>0\!</math> || <math>1\!</math>

| <math>1\!</math> || <math>1\!</math> || <math>1\!</math>

 

 

{| align="center" cellpadding="8" cellspacing="0" style="border-left:1px solid black; border-top:1px solid black; border-right:1px solid black; border-bottom:1px solid black; text-align:center; width:40%"

|+ style="height:30px" | <math>\text{Table 58.} ~~ [| f_{175} |] ~=~ [| p \le r |]\!</math>

| <math>0\!</math> || <math>0\!</math> || <math>0\!</math>

| <math>0\!</math> || <math>0\!</math> || <math>1\!</math>

| <math>0\!</math> || <math>1\!</math> || <math>0\!</math>

| <math>0\!</math> || <math>1\!</math> || <math>1\!</math>

| <math>1\!</math> || <math>0\!</math> || <math>1\!</math>

| <math>1\!</math> || <math>1\!</math> || <math>1\!</math>

{| align="center" cellpadding="8" cellspacing="0" style="border-left:1px solid black; border-top:1px solid black; border-right:1px solid black; border-bottom:1px solid black; text-align:center; width:40%"

|+ style="height:30px" | <math>\text{Table 59.} ~~ [| f_{139} |] ~=~ [| p \le q \le r |]\!</math>

| <math>1\!</math> || <math>1\!</math> || <math>1\!</math>

<br>

 

 

First, we drew a distinction between information preserving and information reducing processes and we noted the related distinction between equational and implicational inferences.  I will use the acronyms EROI and IROI, respectively, for the equational and implicational analogues of the various rules of inference.

For example, we considered the brands of ''information fusion'' that are involved in a couple of standard rules of inference, taken in both their equational and their illative variants.

In particular, let us assume that we begin from a state of uncertainty about the universe of discourse <math>X = \mathbb{B}^3\!</math> that is standardly represented by a uniform distribution <math>u : X \to \mathbb{B}\!</math> such that <math>u(x) = 1\!</math> for all <math>x\!</math> in <math>X,\!</math> in short, by the constant proposition <math>1 : X \to \mathbb{B}.\!</math>  This amounts to the ''maximum entropy sign state'' (MESS). As a measure of uncertainty, let us use either the multiplicative measure given by the cardinality of <math>X,\!</math> commonly notated as <math>|X|,\!</math> or else the additive measure given by <math>{\log_2 |X|}.\!</math>  In this frame we have <math>{|X| = 8}\!</math> and <math>{\log_2 |X| = 3},\!</math> to wit, 3 bits of doubt.

Let us now consider the various rules of inference for transitivity in the light of their performance as information-developing actions.

{| align="center" cellpadding="4" width="90%"

| <big>&bull;</big>

| colspan="3" | '''Transitive Law''' (Implicational Inference)

| width="1%" | &nbsp;

| valign="top" | <big>&bull;</big>

| colspan="3" | By itself, the information <math>p \le q\!</math> would reduce our uncertainty from <math>\log 8\!</math> bits to <math>\log 6\!</math> bits.

| valign="top" | <big>&bull;</big>

| colspan="3" | By itself, the information <math>q \le r\!</math> would reduce our uncertainty from <math>\log 8\!</math> bits to <math>\log 6\!</math> bits.

| valign="top" | <big>&bull;</big>

 

In this situation the application of the implicational rule of inference for transitivity to the information <math>p \le q\!</math> and the information <math>q \le r\!</math> to get the information <math>p \le r\!</math> does not increase the measure of information beyond what any one of the three propositions has independently of the other two. In a sense, then, the implicational rule operates only to move the information around without changing its measure in the slightest bit.

 

| colspan="3" | '''Transitive Law''' (Equational Inference)

| width="1%" | &nbsp;

| valign="top" | <big>&bull;</big>

| colspan="3" | The contents and the measures of information that are associated with the propositions <math>p \le q\!</math> and <math>q \le r\!</math> are the same as before.

| valign="top" | <big>&bull;</big>

 

 

For ease of reference in the rest of this discussion, let us refer to the propositional form <math>f : \mathbb{B}^3 \to \mathbb{B}\!</math> such that <math>f(p, q, r) = f_{139}(p, q, r) = \texttt{(} p \texttt{(} q \texttt{))(} q \texttt{(} r \texttt{))}\!</math> as the ''syllogism map'', written as <math>\mathrm{syll} : \mathbb{B}^3 \to \mathbb{B},\!</math> and let us refer to its fiber of truth <math>[| \mathrm{syll} |] = \mathrm{syll}^{-1}(1)\!</math> as the ''syllogism relation'', written as <math>\mathrm{Syll} \subseteq \mathbb{B}^3.\!</math>  Table&nbsp;60 shows <math>\mathrm{Syll}\!</math> as a relational dataset.

 

 

|+ style="height:30px" | <math>\text{Table 60.} ~~ \text{Syllogism Relation}\!</math>

| style="border-bottom:1px solid black" | <math>r\!</math>

| <math>0\!</math> || <math>0\!</math> || <math>0\!</math>

| <math>0\!</math> || <math>0\!</math> || <math>1\!</math>

| <math>0\!</math> || <math>1\!</math> || <math>1\!</math>

| <math>1\!</math> || <math>1\!</math> || <math>1\!</math>

 

One of the first questions that we might ask about a 3-adic relation, in this case <math>\mathrm{Syll},\!</math> is whether it is ''determined by'' its 2-adic projections.  I will illustrate what this means in the present case.

 

Table&nbsp;61 repeats the relation <math>\mathrm{Syll}\!</math> in the first column, listing its 3-tuples in bit-string form, followed by the 2-adic or ''planar'' projections of <math>\mathrm{Syll}\!</math> in the next three columns.  For instance, <math>\mathrm{Syll}_{pq}\!</math> is the 2-adic projection of <math>\mathrm{Syll}\!</math> on the <math>pq\!</math> plane that is arrived at by deleting the <math>r\!</math> column and counting each 2-tuple that results just one time.  Likewise, <math>\mathrm{Syll}_{pr}\!</math> is obtained by deleting the <math>q\!</math> column and <math>\mathrm{Syll}_{qr}\!</math> is derived by deleting the <math>p\!</math> column, ignoring whatever duplicate pairs may result.  The final row of the right three columns gives the propositions of the form <math>f : \mathbb{B}^2 \to \mathbb{B}\!</math> that indicate the 2-adic relations that result from these projections.

 

{| align="center" border="1" cellpadding="8" cellspacing="0" style="text-align:center; width:80%"

<math>\begin{matrix}

|

0~0 \\ 0~1 \\ 1~1 \\ 1~1

|- style="height:40px; background:#f0f0ff"

| <math>p \le q \le r\!</math>

| <math>\texttt{(} p \texttt{ (} q \texttt{))}\!</math>

| <math>\texttt{(} p \texttt{ (} r \texttt{))}\!</math>

| <math>\texttt{(} q \texttt{ (} r \texttt{))}\!</math>

<br>

 

 

 

 

 

 

The function <math>f_{139} : \mathbb{B}^3 \to \mathbb{B}\!</math> and its fiber <math>[| f_{139} |] \subseteq \mathbb{B}^3\!</math> appeared to be key to many structures in this setting, and so I singled them out under the new names of <math>\mathrm{syll} : \mathbb{B}^3 \to \mathbb{B}\!</math> and <math>\mathrm{Syll} \subseteq \mathbb{B}^3,\!</math> respectively.

 

Managing the conceptual complexity of our considerations at this juncture put us in need of some conceptual tools that I broke off to develop in my notes on "Reductions Among Relations".  The main items that we need right away from that thread are the definitions of relational projections and their inverses, the tacit extensions.

 

Figure&nbsp;62 shows the familiar picture of a boolean 3-cube, where the points of <math>\mathbb{B}^3\!</math> are coordinated as bit strings of length three.  Looking at the functions <math>f : \mathbb{B}^3 \to \mathbb{B}\!</math> and the relations <math>L \subseteq \mathbb{B}^3\!</math> on this pattern, one views the construction of either type of object as a matter of coloring the nodes of the 3-cube with choices from a pair of colors that stipulate which points are in the relation <math>{L = [| f |]}\!</math> and which points are out of it.  Bowing to common convention, we may use the color <math>1\!</math> for points that are ''in'' a given relation and the color <math>0\!</math> for points that are ''out'' of the same relation.  However, it will be more convenient here to indicate the former case by writing the coordinates in the place of the node and to indicate the latter case by plotting the point as an unlabeled node "o".

{| align="center" border="0" cellpadding="10"

|

|                                                 |

| (62)

Table&nbsp;63 shows the 3-adic relation <math>\mathrm{Syll} \subseteq \mathbb{B}^3\!</math> again, and Figure&nbsp;64 shows it plotted on a 3-cube template.

{| align="center" border="0" cellpadding="10"

o-----------------------o

|   p      q      r  |

o-----------------------o

|   0      0      0   |

|   0      0       1   |

|   0      1      1  |

|   1      1      1   |

o-----------------------o

| (63)

 

| (64)

We return once more to the plane projections of <math>\mathrm{Syll} \subseteq \mathbb{B}^3.\!</math>

{| align="center" border="0" cellpadding="10"

|   0      0       0   |

o-----------------------o

| (65)

 

| (66)

Figure&nbsp;67 shows <math>\mathrm{Syll}\!</math> and its three 2-adic projections:

{| align="center" border="0" cellpadding="10"

{| align="center" border="0" cellpadding="10"

|

<pre>

|  (p (q))  | |  (p (r))  | |  (q (r)) |

</pre>

Table 70.  Tacit Extensions of Projections of Syll

{| align="center" border="0" cellpadding="10"

|

|      o      01.                                 |

|            00.                                 |

|                                                 |

| (71)

|                      1.1                      |

{| align="center" border="0" cellpadding="10"

o-------------------------------------------------o

|                       /|\                      |

|               | \  /  \  / |                |

|               |  \ /    \ /  |                |

|               |  \      /  |                |

|               |  / \    / \  |                |

|               | /  \  /  \ |                |

|               |/    \ /    \|                |

|               100      o      001              |

|                 \      |      /                |

|                 \    |    /          .11    |

|                   \    |    /          /|      |

|                   \  |  /          / |      |

|                     \  |  /          /  |      |

|                     \ | /          /  |      |

|                       \|/          /    |      |

|                       000          /    |      |

|                                   /      |      |

|                                 o      .01    |

|                                 |      /      |

|                                 |    /        |

|                                 |    /        |

|                                 |  /          |

|                                 |  /          |

|                                 | /            |

|                                 |/            |

|                                 .00            |

|                                                 |

| (73)

The reader may wish to contemplate Figure&nbsp;74 and use it to verify the following two facts:

{| align="center" cellpadding="8" width="90%"

<math>\begin{array}{lcc}

& = &

\\[6pt]

 

| (74)

In accord with my experimental way, I will stick with the case of transitive inference until I have pinned it down thoroughly, but of course the real interest is much more general than that.

 

{| align="center" border="0" cellpadding="10"

<pre>

              |      (p (r))      |             

Figure 75. Expressive Aspects of Transitive Inference

</pre>

Most of the customary names for this type of process have turned out to have misleading connotations, and so I will experiment with calling it the ''expressive'' aspect of the various rules for transitive inference, simply to emphasize the fact that rules can be given for it that operate solely on signs and expressions, without necessarily needing to look at the objects that are denoted by these signs and expressions.

In the way of many experiments, the word ''expressive'' does not seem to work for what I wanted to say here, since we too often use it to suggest something that expresses an object or a purpose, and I wanted it to imply what is purely a matter of expression, shorn of consideration for anything objective.  Aside from coining a word like ''ennotative'', some other options would be ''connotative'', ''hermeneutic'', ''semiotic'', ''syntactic'' &mdash; each of which works in some range of interpretation but fails in others.  Let's try ''formulaic''.

Despite how simple the formulaic aspects of transitive inference might appear on the surface, there are problems that wait for us just beneath the syntactic surface, as we quickly discover if we turn to considering the kinds of objects, abstract and concrete, that these formulas are meant to denote, and all the more so if we try to do this in a context of computational implementations, where the "interpreters" to be addressed take nothing on faith.  Thus we engage the ''denotative semantics'' or the ''model theory'' of these extremely simple programs that we call ''propositions''.

Figure&nbsp;76 is an attempt to outline the model-theoretic relationships that are involved in our study of transitive inference.  A couple of alternative notations are introduced in this Table:

| The forms <math>X:Y:Z\!</math> and <math>x:y:z\!</math> are used as alternative notations for the cartesian product <math>X \times Y \times Z\!</math> and the tuple <math>(x, y, z),\!</math> respectively.

| In situations where we have products like <math>X:Y:Z\!</math> with <math>X = Y = Z = \mathbb{B},\!</math> and relations like <math>{L \subseteq X:Y},\!</math> &nbsp; <math>{M \subseteq X:Z},\!</math> &nbsp; <math>{N \subseteq Y:Z},\!</math> the forms <math>{L \subseteq \mathbb{B}:\mathbb{B}:-},\!</math> &nbsp; <math>{M \subseteq \mathbb{B}:-:\mathbb{B}},\!</math> &nbsp; <math>{N \subseteq -:\mathbb{B}:\mathbb{B}}\!</math> are used to remind us that we are considering particular ways of situating <math>{L, M, N}\!</math> within the product space <math>X:Y:Z.\!</math>

Figure 76.  Denotative Aspects of Transitive Inference

A piece of syntax like <math>{}^{\backprime\backprime} \texttt{(} p \texttt{(} q \texttt{))} {}^{\prime\prime}\!</math> or <math>{}^{\backprime\backprime} p \Rightarrow q {}^{\prime\prime}\!</math> is an abstract description, and abstraction is a process that loses information about the objects described.  So when we go to reverse the abstraction, as we do when we look for models of that description, there is a degree of indefiniteness that comes into play.

For example, the proposition <math>\texttt{(} p \texttt{(} q \texttt{))}\!</math> is typically assigned the functional type <math>\mathbb{B}^2 \to \mathbb{B},\!</math> but that is only its canonical or its minimal abstract type.  No sooner do we use it in a context that invokes additional variables, as we do when we next consider the proposition <math>\texttt{(} q \texttt{(} r \texttt{))},\!</math> than its type is tacitly adjusted to fit the new context, for instance, acquiring the extended type <math>{\mathbb{B}^3 \to \mathbb{B}}.\!</math>  This is one of those things that most people eventually learn to do without blinking an eye, that is to say, unreflectively, and this is precisely what makes the same facility so much trouble to implement properly in computational form.

Both the fibering operation, that takes us from the function <math>\texttt{(} p \texttt{(} q \texttt{))}\!</math> to the relation <math>[| \texttt{(} p \texttt{(} q \texttt{))} |],\!</math> and the tacit extension operation, that takes us from the relation <math>[| \texttt{(} p \texttt{(} q \texttt{))} |] \subseteq \mathbb{B}:\mathbb{B}\!</math> to the relation <math>[| q_{207} |] \subseteq \mathbb{B}:\mathbb{B}:\mathbb{B},\!</math> have this same character of abstraction-undoing or modelling operations that require us to re-interpret the same pieces of syntax under different types. This accounts for a large part of the apparent ambiguities.

Up till now I've concentrated mostly on the abstract types of domains and propositions, things like <math>\mathbb{B}^k\!</math> and <math>\mathbb{B}^k \to \mathbb{B},\!</math> respectively.  This is a little like trying to do physics all in dimensionless quantities without keeping track of the qualitative physical units.  So much abstraction has its obvious limits, not to mention its hidden dangers.

To remedy this situation I will start to introduce the concrete types of domains and propositions, once again as they pertain to our current collection of examples.