Changes

A set of logical features, <math>\mathcal{A} = \{ a_1, \ldots, a_n \},</math> affords a basis for generating an <math>n\!</math>-dimensional universe of discourse, written <math>A^\circ = [ \mathcal{A} ] = [ a_1, \ldots, a_n ].</math>  It is useful to consider a universe of discourse as a categorical object that incorporates both the set of points <math>A = \langle a_1, \ldots, a_n \rangle</math> and the set of propositions <math>A^\uparrow = \{ f : A \to \mathbb{B} \}</math> that are implicit with the ordinary picture of a venn diagram on <math>n\!</math> features.  Accordingly, the universe of discourse <math>A^\circ</math> may be regarded as an ordered pair <math>(A, A^\uparrow)</math> having the type <math>(\mathbb{B}^n, (\mathbb{B}^n \to \mathbb{B})),</math> and this last type designation may be abbreviated as <math>\mathbb{B}^n\ +\!\to \mathbb{B},</math> or even more succinctly as <math>[ \mathbb{B}^n ].</math>  For convenience, the data type of a finite set on <math>n\!</math> elements may be indicated by either one of the equivalent notations, <math>[n]\!</math> or <math>\mathbf{n}.</math>

A set of logical features, <math>\mathcal{A} = \{ a_1, \ldots, a_n \},</math> affords a basis for generating an <math>n\!</math>-dimensional universe of discourse, written <math>A^\circ = [ \mathcal{A} ] = [ a_1, \ldots, a_n ].</math>  It is useful to consider a universe of discourse as a categorical object that incorporates both the set of points <math>A = \langle a_1, \ldots, a_n \rangle</math> and the set of propositions <math>A^\uparrow = \{ f : A \to \mathbb{B} \}</math> that are implicit with the ordinary picture of a venn diagram on <math>n\!</math> features.  Accordingly, the universe of discourse <math>A^\circ</math> may be regarded as an ordered pair <math>(A, A^\uparrow)</math> having the type <math>(\mathbb{B}^n, (\mathbb{B}^n \to \mathbb{B})),</math> and this last type designation may be abbreviated as <math>\mathbb{B}^n\ +\!\to \mathbb{B},</math> or even more succinctly as <math>[ \mathbb{B}^n ].</math>  For convenience, the data type of a finite set on <math>n\!</math> elements may be indicated by either one of the equivalent notations, <math>[n]\!</math> or <math>\mathbf{n}.</math>

Table 5 summarizes the notations that are needed to describe ordinary propositional calculi in a systematic fashion.

Table&nbsp;5 summarizes the notations that are needed to describe ordinary propositional calculi in a systematic fashion.

{| align="center" border="1" cellpadding="8" cellspacing="0" style="text-align:left; width:96%"

 

{| align="center" border="1" cellpadding="8" cellspacing="0" style="background:#f8f8ff; text-align:left; width:90%"

|+ '''Table 5.  Propositional Calculus : Basic Notation'''

|+ '''Table 5.  Propositional Calculus : Basic Notation'''

|- style="background:ghostwhite"

|- style="background:#e6e6ff"

! Symbol

! Symbol

! Notation

! Notation

|-

|-

| <math>A\!</math>

| <math>A\!</math>

| <math>\langle \mathcal{A} \rangle</math><br>

|

<math>\langle \mathcal{A} \rangle</math><br>

<math>\langle a_1, \ldots, a_n \rangle</math><br>

<math>\langle a_1, \ldots, a_n \rangle</math><br>

<math>\{ (a_1, \ldots, a_n) \}\!</math>

<math>\{ (a_1, \ldots, a_n) \}\!</math>

<math>A_1 \times \ldots \times A_n</math><br>

<math>A_1 \times \ldots \times A_n</math><br>

<math>\textstyle \prod_i A_i\!</math>

<math>\textstyle \prod_i A_i\!</math>

| Set of cells,<br>

|

Set of cells,<br>

coordinate tuples,<br>

coordinate tuples,<br>

points, or vectors<br>

points, or vectors<br>

|-

|-

| <math>A^\circ</math>

| <math>A^\circ</math>

| <math>[ \mathcal{A} ]</math><br>

|

<math>[ \mathcal{A} ]</math><br>

<math>(A, A^\uparrow)</math><br>

<math>(A, A^\uparrow)</math><br>

<math>(A\ +\!\to \mathbb{B})</math><br>

<math>(A\ +\!\to \mathbb{B})</math><br>

<math>(A, (A \to \mathbb{B}))</math><br>

<math>(A, (A \to \mathbb{B}))</math><br>

<math>[ a_1, \ldots, a_n ]</math>

<math>[ a_1, \ldots, a_n ]</math>

| Universe of discourse<br>

|

Universe of discourse<br>

based on the features<br>

based on the features<br>

<math>\{ a_1, \ldots, a_n \}</math>

<math>\{ a_1, \ldots, a_n \}</math>

| <math>(\mathbb{B}^n, (\mathbb{B}^n \to \mathbb{B}))</math><br>

|

<math>(\mathbb{B}^n, (\mathbb{B}^n \to \mathbb{B}))</math><br>

<math>(\mathbb{B}^n\ +\!\to \mathbb{B})</math><br>

<math>(\mathbb{B}^n\ +\!\to \mathbb{B})</math><br>

<math>[\mathbb{B}^n]</math>

<math>[\mathbb{B}^n]</math>

|}

|}

<br>

<br>

A proposition in a differential extension of a universe of discourse is called a ''differential proposition'' and forms the analogue of a system of differential equations in ordinary calculus.  With these constructions, the first order extended universe <math>\operatorname{E}A^\circ</math> and the first order differential proposition <math>f : \operatorname{E}A \to \mathbb{B},</math> we have arrived, in concept at least, at the foothills of [[differential logic]].

A proposition in a differential extension of a universe of discourse is called a ''differential proposition'' and forms the analogue of a system of differential equations in ordinary calculus.  With these constructions, the first order extended universe <math>\operatorname{E}A^\circ</math> and the first order differential proposition <math>f : \operatorname{E}A \to \mathbb{B},</math> we have arrived, in concept at least, at the foothills of [[differential logic]].

Table 6 summarizes the notations that are needed to describe the first order differential extensions of propositional calculi in a systematic manner.

Table&nbsp;6 summarizes the notations that are needed to describe the first order differential extensions of propositional calculi in a systematic manner.

 

{| align="center" border="1" cellpadding="8" cellspacing="0" style="text-align:left; width:96%"

{| align="center" border="1" cellpadding="8" cellspacing="0" style="background:#f8f8ff; text-align:left; width:90%"

|+ '''Table 6.  Differential Extension : Basic Notation'''

|+ '''Table 6.  Differential Extension : Basic Notation'''

|- style="background:ghostwhite"

|- style="background:#e6e6ff"

! Symbol

! Symbol

! Notation

! Notation

| <math>\operatorname{d}\mathfrak{A}</math>

| <math>\operatorname{d}\mathfrak{A}</math>

| <math>\lbrace\!</math>&nbsp;“<math>\operatorname{d}a_1</math>”&nbsp;<math>, \ldots,\!</math>&nbsp;“<math>\operatorname{d}a_n</math>”&nbsp;<math>\rbrace\!</math>

| <math>\lbrace\!</math>&nbsp;“<math>\operatorname{d}a_1</math>”&nbsp;<math>, \ldots,\!</math>&nbsp;“<math>\operatorname{d}a_n</math>”&nbsp;<math>\rbrace\!</math>

| Alphabet of<br>

|

Alphabet of<br>

differential<br>

differential<br>

symbols

symbols

| <math>\operatorname{d}\mathcal{A}</math>

| <math>\operatorname{d}\mathcal{A}</math>

| <math>\{ \operatorname{d}a_1, \ldots, \operatorname{d}a_n \}</math>

| <math>\{ \operatorname{d}a_1, \ldots, \operatorname{d}a_n \}</math>

| Basis of<br>

|

Basis of<br>

differential<br>

differential<br>

features

features

| <math>\operatorname{d}A_i</math>

| <math>\operatorname{d}A_i</math>

| <math>\{ \overline{\operatorname{d}a_i}, \operatorname{d}a_i \}</math>

| <math>\{ \overline{\operatorname{d}a_i}, \operatorname{d}a_i \}</math>

| Differential<br>

|

Differential<br>

dimension <math>i\!</math>

dimension <math>i\!</math>

| <math>\mathbb{D}</math>

| <math>\mathbb{D}</math>

|-

|-

| <math>\operatorname{d}A</math>

| <math>\operatorname{d}A</math>

| <math>\langle \operatorname{d}\mathcal{A} \rangle</math><br>

|

<math>\langle \operatorname{d}\mathcal{A} \rangle</math><br>

<math>\langle \operatorname{d}a_1, \ldots, \operatorname{d}a_n \rangle</math><br>

<math>\langle \operatorname{d}a_1, \ldots, \operatorname{d}a_n \rangle</math><br>

<math>\{ (\operatorname{d}a_1, \ldots, \operatorname{d}a_n) \}</math><br>

<math>\{ (\operatorname{d}a_1, \ldots, \operatorname{d}a_n) \}</math><br>

<math>\operatorname{d}A_1 \times \ldots \times \operatorname{d}A_n</math><br>

<math>\operatorname{d}A_1 \times \ldots \times \operatorname{d}A_n</math><br>

<math>\textstyle \prod_i \operatorname{d}A_i</math>

<math>\textstyle \prod_i \operatorname{d}A_i</math>

| Tangent space<br>

|

Tangent space<br>

at a point:<br>

at a point:<br>

Set of changes,<br>

Set of changes,<br>

| <math>\operatorname{d}A^*</math>

| <math>\operatorname{d}A^*</math>

| <math>(\operatorname{hom} : \operatorname{d}A \to \mathbb{B})</math>

| <math>(\operatorname{hom} : \operatorname{d}A \to \mathbb{B})</math>

| Linear functions<br>

|

Linear functions<br>

on <math>\operatorname{d}A</math>

on <math>\operatorname{d}A</math>

| <math>(\mathbb{D}^n)^* \cong \mathbb{D}^n</math>

| <math>(\mathbb{D}^n)^* \cong \mathbb{D}^n</math>

| <math>\operatorname{d}A^\uparrow</math>

| <math>\operatorname{d}A^\uparrow</math>

| <math>(\operatorname{d}A \to \mathbb{B})</math>

| <math>(\operatorname{d}A \to \mathbb{B})</math>

| Boolean functions<br>

|

Boolean functions<br>

on <math>\operatorname{d}A</math>

on <math>\operatorname{d}A</math>

| <math>\mathbb{D}^n \to \mathbb{B}</math>

| <math>\mathbb{D}^n \to \mathbb{B}</math>

|-

|-

| <math>\operatorname{d}A^\circ</math>

| <math>\operatorname{d}A^\circ</math>

| <math>[\operatorname{d}\mathcal{A}]</math><br>

|

<math>[\operatorname{d}\mathcal{A}]</math><br>

<math>(\operatorname{d}A, \operatorname{d}A^\uparrow)</math><br>

<math>(\operatorname{d}A, \operatorname{d}A^\uparrow)</math><br>

<math>(\operatorname{d}A\ +\!\to \mathbb{B})</math><br>

<math>(\operatorname{d}A\ +\!\to \mathbb{B})</math><br>

<math>(\operatorname{d}A, (\operatorname{d}A \to \mathbb{B}))</math><br>

<math>(\operatorname{d}A, (\operatorname{d}A \to \mathbb{B}))</math><br>

<math>[\operatorname{d}a_1, \ldots, \operatorname{d}a_n]</math>

<math>[\operatorname{d}a_1, \ldots, \operatorname{d}a_n]</math>

| Tangent universe<br>

|

Tangent universe<br>

at a point of <math>A^\circ,</math><br>

at a point of <math>A^\circ,</math><br>

based on the<br>

based on the<br>

tangent features<br>

tangent features<br>

<math>\{ \operatorname{d}a_1, \ldots, \operatorname{d}a_n \}</math>

<math>\{ \operatorname{d}a_1, \ldots, \operatorname{d}a_n \}</math>

| <math>(\mathbb{D}^n, (\mathbb{D}^n \to \mathbb{B}))</math><br>

|

<math>(\mathbb{D}^n, (\mathbb{D}^n \to \mathbb{B}))</math><br>

<math>(\mathbb{D}^n\ +\!\to \mathbb{B})</math><br>

<math>(\mathbb{D}^n\ +\!\to \mathbb{B})</math><br>

<math>[\mathbb{D}^n]</math>

<math>[\mathbb{D}^n]</math>

|}

|}

<br>

<br>