Difference between revisions of "User:Jon Awbrey/TABLE"

Differential Logic

Ascii Tables

Table 1.  Propositional Forms On Two Variables
o---------o---------o---------o----------o------------------o----------o
| L_1     | L_2     | L_3     | L_4      | L_5              | L_6      |
|         |         |         |          |                  |          |
| Decimal | Binary  | Vector  | Cactus   | English          | Ordinary |
o---------o---------o---------o----------o------------------o----------o
|         |       x : 1 1 0 0 |          |                  |          |
|         |       y : 1 0 1 0 |          |                  |          |
o---------o---------o---------o----------o------------------o----------o
|         |         |         |          |                  |          |
| f_0     | f_0000  | 0 0 0 0 |    ()    | false            |    0     |
|         |         |         |          |                  |          |
| f_1     | f_0001  | 0 0 0 1 |  (x)(y)  | neither x nor y  | ~x & ~y  |
|         |         |         |          |                  |          |
| f_2     | f_0010  | 0 0 1 0 |  (x) y   | y and not x      | ~x &  y  |
|         |         |         |          |                  |          |
| f_3     | f_0011  | 0 0 1 1 |  (x)     | not x            | ~x       |
|         |         |         |          |                  |          |
| f_4     | f_0100  | 0 1 0 0 |   x (y)  | x and not y      |  x & ~y  |
|         |         |         |          |                  |          |
| f_5     | f_0101  | 0 1 0 1 |     (y)  | not y            |      ~y  |
|         |         |         |          |                  |          |
| f_6     | f_0110  | 0 1 1 0 |  (x, y)  | x not equal to y |  x +  y  |
|         |         |         |          |                  |          |
| f_7     | f_0111  | 0 1 1 1 |  (x  y)  | not both x and y | ~x v ~y  |
|         |         |         |          |                  |          |
| f_8     | f_1000  | 1 0 0 0 |   x  y   | x and y          |  x &  y  |
|         |         |         |          |                  |          |
| f_9     | f_1001  | 1 0 0 1 | ((x, y)) | x equal to y     |  x =  y  |
|         |         |         |          |                  |          |
| f_10    | f_1010  | 1 0 1 0 |      y   | y                |       y  |
|         |         |         |          |                  |          |
| f_11    | f_1011  | 1 0 1 1 |  (x (y)) | not x without y  |  x => y  |
|         |         |         |          |                  |          |
| f_12    | f_1100  | 1 1 0 0 |   x      | x                |  x       |
|         |         |         |          |                  |          |
| f_13    | f_1101  | 1 1 0 1 | ((x) y)  | not y without x  |  x <= y  |
|         |         |         |          |                  |          |
| f_14    | f_1110  | 1 1 1 0 | ((x)(y)) | x or y           |  x v  y  |
|         |         |         |          |                  |          |
| f_15    | f_1111  | 1 1 1 1 |   (())   | true             |    1     |
|         |         |         |          |                  |          |
o---------o---------o---------o----------o------------------o----------o

Table 2.  Ef Expanded Over Ordinary Features {x, y}
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
|      |     f      |  Ef | xy   | Ef | x(y)  | Ef | (x)y  | Ef | (x)(y)|
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_0  |     ()     |     ()     |     ()     |     ()     |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_1  |   (x)(y)   |   dx  dy   |   dx (dy)  |  (dx) dy   |  (dx)(dy)  |
|      |            |            |            |            |            |
| f_2  |   (x) y    |   dx (dy)  |   dx  dy   |  (dx)(dy)  |  (dx) dy   |
|      |            |            |            |            |            |
| f_4  |    x (y)   |  (dx) dy   |  (dx)(dy)  |   dx  dy   |   dx (dy)  |
|      |            |            |            |            |            |
| f_8  |    x  y    |  (dx)(dy)  |  (dx) dy   |   dx (dy)  |   dx  dy   |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_3  |   (x)      |   dx       |   dx       |  (dx)      |  (dx)      |
|      |            |            |            |            |            |
| f_12 |    x       |  (dx)      |  (dx)      |   dx       |   dx       |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_6  |   (x, y)   |  (dx, dy)  | ((dx, dy)) | ((dx, dy)) |  (dx, dy)  |
|      |            |            |            |            |            |
| f_9  |  ((x, y))  | ((dx, dy)) |  (dx, dy)  |  (dx, dy)  | ((dx, dy)) |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_5  |      (y)   |       dy   |      (dy)  |       dy   |      (dy)  |
|      |            |            |            |            |            |
| f_10 |       y    |      (dy)  |       dy   |      (dy)  |       dy   |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_7  |   (x  y)   | ((dx)(dy)) | ((dx) dy)  |  (dx (dy)) |  (dx  dy)  |
|      |            |            |            |            |            |
| f_11 |   (x (y))  | ((dx) dy)  | ((dx)(dy)) |  (dx  dy)  |  (dx (dy)) |
|      |            |            |            |            |            |
| f_13 |  ((x) y)   |  (dx (dy)) |  (dx  dy)  | ((dx)(dy)) | ((dx) dy)  |
|      |            |            |            |            |            |
| f_14 |  ((x)(y))  |  (dx  dy)  |  (dx (dy)) | ((dx) dy)  | ((dx)(dy)) |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_15 |    (())    |    (())    |    (())    |    (())    |    (())    |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o

Table 3.  Df Expanded Over Ordinary Features {x, y}
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
|      |     f      |  Df | xy   | Df | x(y)  | Df | (x)y  | Df | (x)(y)|
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_0  |     ()     |     ()     |     ()     |     ()     |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_1  |   (x)(y)   |   dx  dy   |   dx (dy)  |  (dx) dy   | ((dx)(dy)) |
|      |            |            |            |            |            |
| f_2  |   (x) y    |   dx (dy)  |   dx  dy   | ((dx)(dy)) |  (dx) dy   |
|      |            |            |            |            |            |
| f_4  |    x (y)   |  (dx) dy   | ((dx)(dy)) |   dx  dy   |   dx (dy)  |
|      |            |            |            |            |            |
| f_8  |    x  y    | ((dx)(dy)) |  (dx) dy   |   dx (dy)  |   dx  dy   |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_3  |   (x)      |   dx       |   dx       |   dx       |   dx       |
|      |            |            |            |            |            |
| f_12 |    x       |   dx       |   dx       |   dx       |   dx       |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_6  |   (x, y)   |  (dx, dy)  |  (dx, dy)  |  (dx, dy)  |  (dx, dy)  |
|      |            |            |            |            |            |
| f_9  |  ((x, y))  |  (dx, dy)  |  (dx, dy)  |  (dx, dy)  |  (dx, dy)  |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_5  |      (y)   |       dy   |       dy   |       dy   |       dy   |
|      |            |            |            |            |            |
| f_10 |       y    |       dy   |       dy   |       dy   |       dy   |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_7  |   (x  y)   | ((dx)(dy)) |  (dx) dy   |   dx (dy)  |   dx  dy   |
|      |            |            |            |            |            |
| f_11 |   (x (y))  |  (dx) dy   | ((dx)(dy)) |   dx  dy   |   dx (dy)  |
|      |            |            |            |            |            |
| f_13 |  ((x) y)   |   dx (dy)  |   dx  dy   | ((dx)(dy)) |  (dx) dy   |
|      |            |            |            |            |            |
| f_14 |  ((x)(y))  |   dx  dy   |   dx (dy)  |  (dx) dy   | ((dx)(dy)) |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_15 |    (())    |     ()     |     ()     |     ()     |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o

Table 4.  Ef Expanded Over Differential Features {dx, dy}
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
|      |     f      |   T_11 f   |   T_10 f   |   T_01 f   |   T_00 f   |
|      |            |            |            |            |            |
|      |            | Ef| dx dy  | Ef| dx(dy) | Ef| (dx)dy | Ef|(dx)(dy)|
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_0  |     ()     |     ()     |     ()     |     ()     |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_1  |   (x)(y)   |    x  y    |    x (y)   |   (x) y    |   (x)(y)   |
|      |            |            |            |            |            |
| f_2  |   (x) y    |    x (y)   |    x  y    |   (x)(y)   |   (x) y    |
|      |            |            |            |            |            |
| f_4  |    x (y)   |   (x) y    |   (x)(y)   |    x  y    |    x (y)   |
|      |            |            |            |            |            |
| f_8  |    x  y    |   (x)(y)   |   (x) y    |    x (y)   |    x  y    |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_3  |   (x)      |    x       |    x       |   (x)      |   (x)      |
|      |            |            |            |            |            |
| f_12 |    x       |   (x)      |   (x)      |    x       |    x       |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_6  |   (x, y)   |   (x, y)   |  ((x, y))  |  ((x, y))  |   (x, y)   |
|      |            |            |            |            |            |
| f_9  |  ((x, y))  |  ((x, y))  |   (x, y)   |   (x, y)   |  ((x, y))  |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_5  |      (y)   |       y    |      (y)   |       y    |      (y)   |
|      |            |            |            |            |            |
| f_10 |       y    |      (y)   |       y    |      (y)   |       y    |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_7  |   (x  y)   |  ((x)(y))  |  ((x) y)   |   (x (y))  |   (x  y)   |
|      |            |            |            |            |            |
| f_11 |   (x (y))  |  ((x) y)   |  ((x)(y))  |   (x  y)   |   (x (y))  |
|      |            |            |            |            |            |
| f_13 |  ((x) y)   |   (x (y))  |   (x  y)   |  ((x)(y))  |  ((x) y)   |
|      |            |            |            |            |            |
| f_14 |  ((x)(y))  |   (x  y)   |   (x (y))  |  ((x) y)   |  ((x)(y))  |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_15 |    (())    |    (())    |    (())    |    (())    |    (())    |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|                   |            |            |            |            |
| Fixed Point Total |      4     |      4     |      4     |     16     |
|                   |            |            |            |            |
o-------------------o------------o------------o------------o------------o

Table 5.  Df Expanded Over Differential Features {dx, dy}
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
|      |     f      | Df| dx dy  | Df| dx(dy) | Df| (dx)dy | Df|(dx)(dy)|
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_0  |     ()     |     ()     |     ()     |     ()     |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_1  |   (x)(y)   |  ((x, y))  |    (y)     |    (x)     |     ()     |
|      |            |            |            |            |            |
| f_2  |   (x) y    |   (x, y)   |     y      |    (x)     |     ()     |
|      |            |            |            |            |            |
| f_4  |    x (y)   |   (x, y)   |    (y)     |     x      |     ()     |
|      |            |            |            |            |            |
| f_8  |    x  y    |  ((x, y))  |     y      |     x      |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_3  |   (x)      |    (())    |    (())    |     ()     |     ()     |
|      |            |            |            |            |            |
| f_12 |    x       |    (())    |    (())    |     ()     |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_6  |   (x, y)   |     ()     |    (())    |    (())    |     ()     |
|      |            |            |            |            |            |
| f_9  |  ((x, y))  |     ()     |    (())    |    (())    |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_5  |      (y)   |    (())    |     ()     |    (())    |     ()     |
|      |            |            |            |            |            |
| f_10 |       y    |    (())    |     ()     |    (())    |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_7  |   (x  y)   |  ((x, y))  |     y      |     x      |     ()     |
|      |            |            |            |            |            |
| f_11 |   (x (y))  |   (x, y)   |    (y)     |     x      |     ()     |
|      |            |            |            |            |            |
| f_13 |  ((x) y)   |   (x, y)   |     y      |    (x)     |     ()     |
|      |            |            |            |            |            |
| f_14 |  ((x)(y))  |  ((x, y))  |    (y)     |    (x)     |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o
|      |            |            |            |            |            |
| f_15 |    (())    |     ()     |     ()     |     ()     |     ()     |
|      |            |            |            |            |            |
o------o------------o------------o------------o------------o------------o

Wiki Tables

Table 1. Propositional Forms on Two Variables

L1	L2	L3	L4	L5	L6
	x :	1 1 0 0
	y :	1 0 1 0
f0	f0000	0 0 0 0	( )	false	0
f1	f0001	0 0 0 1	(x)(y)	neither x nor y	¬x ∧ ¬y
f2	f0010	0 0 1 0	(x) y	y and not x	¬x ∧ y
f3	f0011	0 0 1 1	(x)	not x	¬x
f4	f0100	0 1 0 0	x (y)	x and not y	x ∧ ¬y
f5	f0101	0 1 0 1	(y)	not y	¬y
f6	f0110	0 1 1 0	(x, y)	x not equal to y	x ≠ y
f7	f0111	0 1 1 1	(x y)	not both x and y	¬x ∨ ¬y
f8	f1000	1 0 0 0	x y	x and y	x ∧ y
f9	f1001	1 0 0 1	((x, y))	x equal to y	x = y
f10	f1010	1 0 1 0	y	y	y
f11	f1011	1 0 1 1	(x (y))	not x without y	x → y
f12	f1100	1 1 0 0	x	x	x
f13	f1101	1 1 0 1	((x) y)	not y without x	x ← y
f14	f1110	1 1 1 0	((x)(y))	x or y	x ∨ y
f15	f1111	1 1 1 1	(( ))	true	1

Inquiry Driven Systems

Table 1. Sign Relation of Interpreter A

Table 1.  Sign Relation of Interpreter A
o---------------o---------------o---------------o
| Object        | Sign          | Interpretant  |
o---------------o---------------o---------------o
| A             | "A"           | "A"           |
| A             | "A"           | "i"           |
| A             | "i"           | "A"           |
| A             | "i"           | "i"           |
| B             | "B"           | "B"           |
| B             | "B"           | "u"           |
| B             | "u"           | "B"           |
| B             | "u"           | "u"           |
o---------------o---------------o---------------o

Table 1. Sign Relation of Interpreter A

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"i"
A	"i"	"A"
A	"i"	"i"
B	"B"	"B"
B	"B"	"u"
B	"u"	"B"
B	"u"	"u"

Table 2. Sign Relation of Interpreter B

Table 2.  Sign Relation of Interpreter B
o---------------o---------------o---------------o
| Object        | Sign          | Interpretant  |
o---------------o---------------o---------------o
| A             | "A"           | "A"           |
| A             | "A"           | "u"           |
| A             | "u"           | "A"           |
| A             | "u"           | "u"           |
| B             | "B"           | "B"           |
| B             | "B"           | "i"           |
| B             | "i"           | "B"           |
| B             | "i"           | "i"           |
o---------------o---------------o---------------o

Table 2. Sign Relation of Interpreter B

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"u"
A	"u"	"A"
A	"u"	"u"
B	"B"	"B"
B	"B"	"i"
B	"i"	"B"
B	"i"	"i"

Table 3. Semiotic Partition of Interpreter A

Table 3.  A's Semiotic Partition
o-------------------------------o
|      "A"             "i"      |
o-------------------------------o
|      "u"             "B"      |
o-------------------------------o

Table 3. Semiotic Partition of Interpreter A

"A" "i"

"u" "B"

Table 4. Semiotic Partition of Interpreter B

Table 4.  B's Semiotic Partition
o---------------o---------------o
|      "A"      |      "i"      |
|               |               |
|      "u"      |      "B"      |
o---------------o---------------o

Table 4. Semiotic Partition of Interpreter B

"A" "u"

"i" "B"

Table 5. Alignments of Capacities

Table 5.  Alignments of Capacities
o-------------------o-----------------------------o
|      Formal       |          Formative          |
o-------------------o-----------------------------o
|     Objective     |        Instrumental         |
|      Passive      |           Active            |
o-------------------o--------------o--------------o
|     Afforded      |  Possessed   |  Exercised   |
o-------------------o--------------o--------------o

Table 6. Alignments of Capacities in Aristotle

Table 6.  Alignments of Capacities in Aristotle
o-------------------o-----------------------------o
|      Matter       |            Form             |
o-------------------o-----------------------------o
|   Potentiality    |          Actuality          |
|    Receptivity    |  Possession  |   Exercise   |
|       Life        |    Sleep     |    Waking    |
|        Wax        |         Impression          |
|        Axe        |    Edge      |   Cutting    |
|        Eye        |   Vision     |    Seeing    |
|       Body        |            Soul             |
o-------------------o-----------------------------o
|       Ship?       |           Sailor?           |
o-------------------o-----------------------------o

Table 7. Synthesis of Alignments

Table 7.  Synthesis of Alignments
o-------------------o-----------------------------o
|      Formal       |          Formative          |
o-------------------o-----------------------------o
|     Objective     |        Instrumental         |
|      Passive      |           Active            |
|     Afforded      |  Possessed   |  Exercised   |
|      To Hold      |   To Have    |    To Use    |
|    Receptivity    |  Possession  |   Exercise   |
|   Potentiality    |          Actuality          |
|      Matter       |            Form             |
o-------------------o-----------------------------o

Table 8. Boolean Product

Table 8.  Boolean Product
o---------o---------o---------o
|   %*%   %   %0%   |   %1%   |
o=========o=========o=========o
|   %0%   %   %0%   |   %0%   |
o---------o---------o---------o
|   %1%   %   %0%   |   %1%   |
o---------o---------o---------o

Table 9. Boolean Sum

Table 9.  Boolean Sum
o---------o---------o---------o
|   %+%   %   %0%   |   %1%   |
o=========o=========o=========o
|   %0%   %   %0%   |   %1%   |
o---------o---------o---------o
|   %1%   %   %1%   |   %0%   |
o---------o---------o---------o

Logical Tables

Table Templates

Table 1. Two Variable Template

u : v :	1 1 0 0 1 0 1 0	f	f	f
f0 f1 f2 f3 f4 f5 f6 f7	0 0 0 0 0 0 0 1 0 0 1 0 0 0 1 1 0 1 0 0 0 1 0 1 0 1 1 0 0 1 1 1	f0 f1 f2 f3 f4 f5 f6 f7	f0 f1 f2 f3 f4 f5 f6 f7	f0 f1 f2 f3 f4 f5 f6 f7
f8 f9 f10 f11 f12 f13 f14 f15	1 0 0 0 1 0 0 1 1 0 1 0 1 0 1 1 1 1 0 0 1 1 0 1 1 1 1 0 1 1 1 1	f8 f9 f10 f11 f12 f13 f14 f15	f8 f9 f10 f11 f12 f13 f14 f15	f8 f9 f10 f11 f12 f13 f14 f15

Table 2. Two Variable Template

u : v :	1100 1010	f	f	f
f0 f1 f2 f3 f4 f5 f6 f7	0000 0001 0010 0011 0100 0101 0110 0111	()  (u)(v)   (u) v    (u)       u (v)      (v)   (u, v)   (u  v)	f0 f1 f2 f3 f4 f5 f6 f7	f0 f1 f2 f3 f4 f5 f6 f7
f8 f9 f10 f11 f12 f13 f14 f15	1000 1001 1010 1011 1100 1101 1110 1111	u  v   ((u, v))      v    (u (v))   u      ((u) v)  ((u)(v)) (())	f8 f9 f10 f11 f12 f13 f14 f15	f8 f9 f10 f11 f12 f13 f14 f15

Higher Order Propositions

Table 7. Higher Order Propositions (n = 1)

\ x	1 0	F	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m
F \			00	01	02	03	04	05	06	07	08	09	10	11	12	13	14	15
F0	0 0	0	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1
F1	0 1	(x)	0	0	1	1	0	0	1	1	0	0	1	1	0	0	1	1
F2	1 0	x	0	0	0	0	1	1	1	1	0	0	0	0	1	1	1	1
F3	1 1	1	0	0	0	0	0	0	0	0	1	1	1	1	1	1	1	1

Table 8. Interpretive Categories for Higher Order Propositions (n = 1)

Measure	Happening	Exactness	Existence	Linearity	Uniformity	Information
m0	nothing happens
m1		just false	nothing exists
m2		just not x
m3			nothing is x
m4		just x
m5			everything is x	F is linear
m6					F is not uniform	F is informed
m7		not just true
m8		just true
m9					F is uniform	F is not informed
m10			something is not x	F is not linear
m11		not just x
m12			something is x
m13		not just not x
m14		not just false	something exists
m15	anything happens

Table 9. Higher Order Propositions (n = 2)

x :	1100	f	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m	m
y :	1010		0	1	2	3	4	5	6	7	8	9	10	11	12	13	14	15	16	17	18	19	20	21	22	23
f0	0000	( )	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1
f1	0001	(x)(y)			1	1	0	0	1	1	0	0	1	1	0	0	1	1	0	0	1	1	0	0	1	1
f2	0010	(x) y					1	1	1	1	0	0	0	0	1	1	1	1	0	0	0	0	1	1	1	1
f3	0011	(x)									1	1	1	1	1	1	1	1	0	0	0	0	0	0	0	0
f4	0100	x (y)																	1	1	1	1	1	1	1	1
f5	0101	(y)
f6	0110	(x, y)
f7	0111	(x y)
f8	1000	x y
f9	1001	((x, y))
f10	1010	y
f11	1011	(x (y))
f12	1100	x
f13	1101	((x) y)
f14	1110	((x)(y))
f15	1111	(( ))

Table 10. Qualifiers of Implication Ordering: α_i f = Υ(f_i ⇒ f)

x :	1100	f	α	α	α	α	α	α	α	α	α	α	α	α	α	α	α	α
y :	1010		15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
f0	0000	( )																1
f1	0001	(x)(y)															1	1
f2	0010	(x) y														1		1
f3	0011	(x)													1	1	1	1
f4	0100	x (y)												1				1
f5	0101	(y)											1	1			1	1
f6	0110	(x, y)										1		1		1		1
f7	0111	(x y)									1	1	1	1	1	1	1	1
f8	1000	x y								1								1
f9	1001	((x, y))							1	1							1	1
f10	1010	y						1		1						1		1
f11	1011	(x (y))					1	1	1	1					1	1	1	1
f12	1100	x				1				1				1				1
f13	1101	((x) y)			1	1			1	1			1	1			1	1
f14	1110	((x)(y))		1		1		1		1		1		1		1		1
f15	1111	(( ))	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1

Table 11. Qualifiers of Implication Ordering: β_i f = Υ(f ⇒ f_i)

x :	1100	f	β	β	β	β	β	β	β	β	β	β	β	β	β	β	β	β
y :	1010		0	1	2	3	4	5	6	7	8	9	10	11	12	13	14	15
f0	0000	( )	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1
f1	0001	(x)(y)		1		1		1		1		1		1		1		1
f2	0010	(x) y			1	1			1	1			1	1			1	1
f3	0011	(x)				1				1				1				1
f4	0100	x (y)					1	1	1	1					1	1	1	1
f5	0101	(y)						1		1						1		1
f6	0110	(x, y)							1	1							1	1
f7	0111	(x y)								1								1
f8	1000	x y									1	1	1	1	1	1	1	1
f9	1001	((x, y))										1		1		1		1
f10	1010	y											1	1			1	1
f11	1011	(x (y))												1				1
f12	1100	x													1	1	1	1
f13	1101	((x) y)														1		1
f14	1110	((x)(y))															1	1
f15	1111	(( ))																1

Table 13. Syllogistic Premisses as Higher Order Indicator Functions

A	Universal Affirmative	All	x	is	y	Indicator of " x (y)" = 0
E	Universal Negative	All	x	is	(y)	Indicator of " x y " = 0
I	Particular Affirmative	Some	x	is	y	Indicator of " x y " = 1
O	Particular Negative	Some	x	is	(y)	Indicator of " x (y)" = 1

Table 14. Relation of Quantifiers to Higher Order Propositions

Mnemonic	Category	Classical Form	Alternate Form	Symmetric Form	Operator
E Exclusive	Universal Negative	All x is (y)		No x is y	(L11)
A Absolute	Universal Affirmative	All x is y		No x is (y)	(L10)
		All y is x	No y is (x)	No (x) is y	(L01)
		All (y) is x	No (y) is (x)	No (x) is (y)	(L00)
		Some (x) is (y)		Some (x) is (y)	L00
		Some (x) is y		Some (x) is y	L01
O Obtrusive	Particular Negative	Some x is (y)		Some x is (y)	L10
I Indefinite	Particular Affirmative	Some x is y		Some x is y	L11

Table 15. Simple Qualifiers of Propositions (n = 2)

x :	1100	f	(L11)	(L10)	(L01)	(L00)	L00	L01	L10	L11
y :	1010		no x is y	no x is (y)	no (x) is y	no (x) is (y)	some (x) is (y)	some (x) is y	some x is (y)	some x is y
f0	0000	( )	1	1	1	1	0	0	0	0
f1	0001	(x)(y)	1	1	1	0	1	0	0	0
f2	0010	(x) y	1	1	0	1	0	1	0	0
f3	0011	(x)	1	1	0	0	1	1	0	0
f4	0100	x (y)	1	0	1	1	0	0	1	0
f5	0101	(y)	1	0	1	0	1	0	1	0
f6	0110	(x, y)	1	0	0	1	0	1	1	0
f7	0111	(x y)	1	0	0	0	1	1	1	0
f8	1000	x y	0	1	1	1	0	0	0	1
f9	1001	((x, y))	0	1	1	0	1	0	0	1
f10	1010	y	0	1	0	1	0	1	0	1
f11	1011	(x (y))	0	1	0	0	1	1	0	1
f12	1100	x	0	0	1	1	0	0	1	1
f13	1101	((x) y)	0	0	1	0	1	0	1	1
f14	1110	((x)(y))	0	0	0	1	0	1	1	1
f15	1111	(( ))	0	0	0	0	1	1	1	1

Table 7.  Higher Order Propositions (n = 1)
o------o-----o-----o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o---o
|  \ x | 1 0 |  F  |m |m |m |m |m |m |m |m |m |m |m |m |m |m |m |m  |
| F \  |     |     |00|01|02|03|04|05|06|07|08|09|10|11|12|13|14|15 |
o------o-----o-----o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o---o
|      |     |     |                                                |
| F_0  | 0 0 |  0  | 0  1  0  1  0  1  0  1  0  1  0  1  0  1  0  1 |
|      |     |     |                                                |
| F_1  | 0 1 | (x) | 0  0  1  1  0  0  1  1  0  0  1  1  0  0  1  1 |
|      |     |     |                                                |
| F_2  | 1 0 |  x  | 0  0  0  0  1  1  1  1  0  0  0  0  1  1  1  1 |
|      |     |     |                                                |
| F_3  | 1 1 |  1  | 0  0  0  0  0  0  0  0  1  1  1  1  1  1  1  1 |
|      |     |     |                                                |
o------o-----o-----o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o---o

Table 8.  Interpretive Categories for Higher Order Propositions (n = 1)
o-------o----------o------------o------------o----------o----------o-----------o
|Measure| Happening| Exactness  | Existence  | Linearity|Uniformity|Information|
o-------o----------o------------o------------o----------o----------o-----------o
| m_0   | nothing  |            |            |          |          |           |
|       | happens  |            |            |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_1   |          |            | nothing    |          |          |           |
|       |          | just false | exists     |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_2   |          |            |            |          |          |           |
|       |          | just not x |            |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_3   |          |            | nothing    |          |          |           |
|       |          |            | is x       |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_4   |          |            |            |          |          |           |
|       |          | just x     |            |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_5   |          |            | everything | F is     |          |           |
|       |          |            | is x       | linear   |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_6   |          |            |            |          | F is not | F is      |
|       |          |            |            |          | uniform  | informed  |
o-------o----------o------------o------------o----------o----------o-----------o
| m_7   |          | not        |            |          |          |           |
|       |          | just true  |            |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_8   |          |            |            |          |          |           |
|       |          | just true  |            |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_9   |          |            |            |          | F is     | F is not  |
|       |          |            |            |          | uniform  | informed  |
o-------o----------o------------o------------o----------o----------o-----------o
| m_10  |          |            | something  | F is not |          |           |
|       |          |            | is not x   | linear   |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_11  |          | not        |            |          |          |           |
|       |          | just x     |            |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_12  |          |            | something  |          |          |           |
|       |          |            | is x       |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_13  |          | not        |            |          |          |           |
|       |          | just not x |            |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_14  |          | not        | something  |          |          |           |
|       |          | just false | exists     |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o
| m_15  | anything |            |            |          |          |           |
|       | happens  |            |            |          |          |           |
o-------o----------o------------o------------o----------o----------o-----------o

Table 9.  Higher Order Propositions (n = 2)
o------o------o----------o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o
|  | x | 1100 |    f     |m|m|m|m|m|m|m|m|m|m|m|m|m|m|m|m|.|
|  | y | 1010 |          |0|0|0|0|0|0|0|0|0|0|1|1|1|1|1|1|.|
| f \  |      |          |0|1|2|3|4|5|6|7|8|9|0|1|2|3|4|5|.|
o------o------o----------o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o
|      |      |          |                                 |
| f_0  | 0000 |    ()    |0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1  |
|      |      |          |                                 |
| f_1  | 0001 |  (x)(y)  |    1 1 0 0 1 1 0 0 1 1 0 0 1 1  |
|      |      |          |                                 |
| f_2  | 0010 |  (x) y   |        1 1 1 1 0 0 0 0 1 1 1 1  |
|      |      |          |                                 |
| f_3  | 0011 |  (x)     |                1 1 1 1 1 1 1 1  |
|      |      |          |                                 |
| f_4  | 0100 |   x (y)  |                                 |
|      |      |          |                                 |
| f_5  | 0101 |     (y)  |                                 |
|      |      |          |                                 |
| f_6  | 0110 |  (x, y)  |                                 |
|      |      |          |                                 |
| f_7  | 0111 |  (x  y)  |                                 |
|      |      |          |                                 |
o------o------o----------o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o
|      |      |          |                                 |
| f_8  | 1000 |   x  y   |                                 |
|      |      |          |                                 |
| f_9  | 1001 | ((x, y)) |                                 |
|      |      |          |                                 |
| f_10 | 1010 |      y   |                                 |
|      |      |          |                                 |
| f_11 | 1011 |  (x (y)) |                                 |
|      |      |          |                                 |
| f_12 | 1100 |   x      |                                 |
|      |      |          |                                 |
| f_13 | 1101 | ((x) y)  |                                 |
|      |      |          |                                 |
| f_14 | 1110 | ((x)(y)) |                                 |
|      |      |          |                                 |
| f_15 | 1111 |   (())   |                                 |
|      |      |          |                                 |
o------o------o----------o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o-o

Table 10.  Qualifiers of Implication Ordering:  !a!_i f  =  !Y!(f_i => f)
o------o------o----------o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o
|  | x | 1100 |    f     |a |a |a |a |a |a |a |a |a |a |a |a |a |a |a |a |
|  | y | 1010 |          |1 |1 |1 |1 |1 |1 |0 |0 |0 |0 |0 |0 |0 |0 |0 |0 |
| f \  |      |          |5 |4 |3 |2 |1 |0 |9 |8 |7 |6 |5 |4 |3 |2 |1 |0 |
o------o------o----------o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o
|      |      |          |                                               |
| f_0  | 0000 |    ()    |                                             1 |
|      |      |          |                                               |
| f_1  | 0001 |  (x)(y)  |                                          1  1 |
|      |      |          |                                               |
| f_2  | 0010 |  (x) y   |                                       1     1 |
|      |      |          |                                               |
| f_3  | 0011 |  (x)     |                                    1  1  1  1 |
|      |      |          |                                               |
| f_4  | 0100 |   x (y)  |                                 1           1 |
|      |      |          |                                               |
| f_5  | 0101 |     (y)  |                              1  1        1  1 |
|      |      |          |                                               |
| f_6  | 0110 |  (x, y)  |                           1     1     1     1 |
|      |      |          |                                               |
| f_7  | 0111 |  (x  y)  |                        1  1  1  1  1  1  1  1 |
|      |      |          |                                               |
| f_8  | 1000 |   x  y   |                     1                       1 |
|      |      |          |                                               |
| f_9  | 1001 | ((x, y)) |                  1  1                    1  1 |
|      |      |          |                                               |
| f_10 | 1010 |      y   |               1     1                 1     1 |
|      |      |          |                                               |
| f_11 | 1011 |  (x (y)) |            1  1  1  1              1  1  1  1 |
|      |      |          |                                               |
| f_12 | 1100 |   x      |         1           1           1           1 |
|      |      |          |                                               |
| f_13 | 1101 | ((x) y)  |      1  1        1  1        1  1        1  1 |
|      |      |          |                                               |
| f_14 | 1110 | ((x)(y)) |   1     1     1     1     1     1     1     1 |
|      |      |          |                                               |
| f_15 | 1111 |   (())   |1  1  1  1  1  1  1  1  1  1  1  1  1  1  1  1 |
|      |      |          |                                               |
o------o------o----------o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o

Table 11.  Qualifiers of Implication Ordering:  !b!_i f  =  !Y!(f => f_i)
o------o------o----------o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o
|  | x | 1100 |    f     |b |b |b |b |b |b |b |b |b |b |b |b |b |b |b |b |
|  | y | 1010 |          |0 |0 |0 |0 |0 |0 |0 |0 |0 |0 |1 |1 |1 |1 |1 |1 |
| f \  |      |          |0 |1 |2 |3 |4 |5 |6 |7 |8 |9 |0 |1 |2 |3 |4 |5 |
o------o------o----------o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o
|      |      |          |                                               |
| f_0  | 0000 |    ()    |1  1  1  1  1  1  1  1  1  1  1  1  1  1  1  1 |
|      |      |          |                                               |
| f_1  | 0001 |  (x)(y)  |   1     1     1     1     1     1     1     1 |
|      |      |          |                                               |
| f_2  | 0010 |  (x) y   |      1  1        1  1        1  1        1  1 |
|      |      |          |                                               |
| f_3  | 0011 |  (x)     |         1           1           1           1 |
|      |      |          |                                               |
| f_4  | 0100 |   x (y)  |            1  1  1  1              1  1  1  1 |
|      |      |          |                                               |
| f_5  | 0101 |     (y)  |               1     1                 1     1 |
|      |      |          |                                               |
| f_6  | 0110 |  (x, y)  |                  1  1                    1  1 |
|      |      |          |                                               |
| f_7  | 0111 |  (x  y)  |                     1                       1 |
|      |      |          |                                               |
| f_8  | 1000 |   x  y   |                        1  1  1  1  1  1  1  1 |
|      |      |          |                                               |
| f_9  | 1001 | ((x, y)) |                           1     1     1     1 |
|      |      |          |                                               |
| f_10 | 1010 |      y   |                              1  1        1  1 |
|      |      |          |                                               |
| f_11 | 1011 |  (x (y)) |                                 1           1 |
|      |      |          |                                               |
| f_12 | 1100 |   x      |                                    1  1  1  1 |
|      |      |          |                                               |
| f_13 | 1101 | ((x) y)  |                                       1     1 |
|      |      |          |                                               |
| f_14 | 1110 | ((x)(y)) |                                          1  1 |
|      |      |          |                                               |
| f_15 | 1111 |   (())   |                                             1 |
|      |      |          |                                               |
o------o------o----------o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o--o

Table 13.  Syllogistic Premisses as Higher Order Indicator Functions
o---o------------------------o-----------------o---------------------------o
|   |                        |                 |                           |
| A | Universal Affirmative  | All   x  is  y  | Indicator of " x (y)" = 0 |
|   |                        |                 |                           |
| E | Universal Negative     | All   x  is (y) | Indicator of " x  y " = 0 |
|   |                        |                 |                           |
| I | Particular Affirmative | Some  x  is  y  | Indicator of " x  y " = 1 |
|   |                        |                 |                           |
| O | Particular Negative    | Some  x  is (y) | Indicator of " x (y)" = 1 |
|   |                        |                 |                           |
o---o------------------------o-----------------o---------------------------o

Table 14.  Relation of Quantifiers to Higher Order Propositions
o------------o------------o-----------o-----------o-----------o-----------o
| Mnemonic   | Category   | Classical | Alternate | Symmetric | Operator  |
|            |            |   Form    |   Form    |   Form    |           |
o============o============o===========o===========o===========o===========o
|     E      | Universal  |  All   x  |           |   No   x  |  (L_11)   |
| Exclusive  |  Negative  |   is  (y) |           |   is   y  |           |
o------------o------------o-----------o-----------o-----------o-----------o
|     A      | Universal  |  All   x  |           |   No   x  |  (L_10)   |
| Absolute   |  Affrmtve  |   is   y  |           |   is  (y) |           |
o------------o------------o-----------o-----------o-----------o-----------o
|            |            |  All   y  |   No   y  |   No  (x) |  (L_01)   |
|            |            |   is   x  |   is  (x) |   is   y  |           |
o------------o------------o-----------o-----------o-----------o-----------o
|            |            |  All  (y) |   No  (y) |   No  (x) |  (L_00)   |
|            |            |   is   x  |   is  (x) |   is  (y) |           |
o------------o------------o-----------o-----------o-----------o-----------o
|            |            | Some  (x) |           | Some  (x) |   L_00    |
|            |            |   is  (y) |           |   is  (y) |           |
o------------o------------o-----------o-----------o-----------o-----------o
|            |            | Some  (x) |           | Some  (x) |   L_01    |
|            |            |   is   y  |           |   is   y  |           |
o------------o------------o-----------o-----------o-----------o-----------o
|     O      | Particular | Some   x  |           | Some   x  |   L_10    |
| Obtrusive  |  Negative  |   is  (y) |           |   is  (y) |           |
o------------o------------o-----------o-----------o-----------o-----------o
|     I      | Particular | Some   x  |           | Some   x  |   L_11    |
| Indefinite |  Affrmtve  |   is   y  |           |   is   y  |           |
o------------o------------o-----------o-----------o-----------o-----------o

Table 15.  Simple Qualifiers of Propositions (n = 2)
o------o------o----------o-----o-----o-----o-----o-----o-----o-----o-----o
|  | x | 1100 |    f     |(L11)|(L10)|(L01)|(L00)| L00 | L01 | L10 | L11 |
|  | y | 1010 |          |no  x|no  x|no ~x|no ~x|sm ~x|sm ~x|sm  x|sm  x|
| f \  |      |          |is  y|is ~y|is  y|is ~y|is ~y|is  y|is ~y|is  y|
o------o------o----------o-----o-----o-----o-----o-----o-----o-----o-----o
|      |      |          |                                               |
| f_0  | 0000 |    ()    |  1     1     1     1     0     0     0     0  |
|      |      |          |                                               |
| f_1  | 0001 |  (x)(y)  |  1     1     1     0     1     0     0     0  |
|      |      |          |                                               |
| f_2  | 0010 |  (x) y   |  1     1     0     1     0     1     0     0  |
|      |      |          |                                               |
| f_3  | 0011 |  (x)     |  1     1     0     0     1     1     0     0  |
|      |      |          |                                               |
| f_4  | 0100 |   x (y)  |  1     0     1     1     0     0     1     0  |
|      |      |          |                                               |
| f_5  | 0101 |     (y)  |  1     0     1     0     1     0     1     0  |
|      |      |          |                                               |
| f_6  | 0110 |  (x, y)  |  1     0     0     1     0     1     1     0  |
|      |      |          |                                               |
| f_7  | 0111 |  (x  y)  |  1     0     0     0     1     1     1     0  |
|      |      |          |                                               |
| f_8  | 1000 |   x  y   |  0     1     1     1     0     0     0     1  |
|      |      |          |                                               |
| f_9  | 1001 | ((x, y)) |  0     1     1     0     1     0     0     1  |
|      |      |          |                                               |
| f_10 | 1010 |      y   |  0     1     0     1     0     1     0     1  |
|      |      |          |                                               |
| f_11 | 1011 |  (x (y)) |  0     1     0     0     1     1     0     1  |
|      |      |          |                                               |
| f_12 | 1100 |   x      |  0     0     1     1     0     0     1     1  |
|      |      |          |                                               |
| f_13 | 1101 | ((x) y)  |  0     0     1     0     1     0     1     1  |
|      |      |          |                                               |
| f_14 | 1110 | ((x)(y)) |  0     0     0     1     0     1     1     1  |
|      |      |          |                                               |
| f_15 | 1111 |   (())   |  0     0     0     0     1     1     1     1  |
|      |      |          |                                               |
o------o------o----------o-----o-----o-----o-----o-----o-----o-----o-----o

Zeroth Order Logic

Table 1. Propositional Forms on Two Variables

L1	L2	L3	L4	L5	L6
	x :	1 1 0 0
	y :	1 0 1 0
f0	f0000	0 0 0 0	( )	false	0
f1	f0001	0 0 0 1	(x)(y)	neither x nor y	¬x ∧ ¬y
f2	f0010	0 0 1 0	(x) y	y and not x	¬x ∧ y
f3	f0011	0 0 1 1	(x)	not x	¬x
f4	f0100	0 1 0 0	x (y)	x and not y	x ∧ ¬y
f5	f0101	0 1 0 1	(y)	not y	¬y
f6	f0110	0 1 1 0	(x, y)	x not equal to y	x ≠ y
f7	f0111	0 1 1 1	(x y)	not both x and y	¬x ∨ ¬y
f8	f1000	1 0 0 0	x y	x and y	x ∧ y
f9	f1001	1 0 0 1	((x, y))	x equal to y	x = y
f10	f1010	1 0 1 0	y	y	y
f11	f1011	1 0 1 1	(x (y))	not x without y	x → y
f12	f1100	1 1 0 0	x	x	x
f13	f1101	1 1 0 1	((x) y)	not y without x	x ← y
f14	f1110	1 1 1 0	((x)(y))	x or y	x ∨ y
f15	f1111	1 1 1 1	(( ))	true	1

Table 1. Propositional Forms on Two Variables

L1	L2	L3	L4	L5	L6
	x :	1 1 0 0
	y :	1 0 1 0
f0	f0000	0 0 0 0	( )	false	0
f1	f0001	0 0 0 1	(x)(y)	neither x nor y	¬x ∧ ¬y
f2	f0010	0 0 1 0	(x) y	y and not x	¬x ∧ y
f3	f0011	0 0 1 1	(x)	not x	¬x
f4	f0100	0 1 0 0	x (y)	x and not y	x ∧ ¬y
f5	f0101	0 1 0 1	(y)	not y	¬y
f6	f0110	0 1 1 0	(x, y)	x not equal to y	x ≠ y
f7	f0111	0 1 1 1	(x y)	not both x and y	¬x ∨ ¬y
f8	f1000	1 0 0 0	x y	x and y	x ∧ y
f9	f1001	1 0 0 1	((x, y))	x equal to y	x = y
f10	f1010	1 0 1 0	y	y	y
f11	f1011	1 0 1 1	(x (y))	not x without y	x → y
f12	f1100	1 1 0 0	x	x	x
f13	f1101	1 1 0 1	((x) y)	not y without x	x ← y
f14	f1110	1 1 1 0	((x)(y))	x or y	x ∨ y
f15	f1111	1 1 1 1	(( ))	true	1

Template Draft

Propositional Forms on Two Variables

L1	L2	L3	L4	L5	L6	Name
	x :	1 1 0 0
	y :	1 0 1 0
f0	f0000	0 0 0 0	( )	false	0	Falsity
f1	f0001	0 0 0 1	(x)(y)	neither x nor y	¬x ∧ ¬y	NNOR
f2	f0010	0 0 1 0	(x) y	y and not x	¬x ∧ y	Insuccede
f3	f0011	0 0 1 1	(x)	not x	¬x	Not One
f4	f0100	0 1 0 0	x (y)	x and not y	x ∧ ¬y	Imprecede
f5	f0101	0 1 0 1	(y)	not y	¬y	Not Two
f6	f0110	0 1 1 0	(x, y)	x not equal to y	x ≠ y	Inequality
f7	f0111	0 1 1 1	(x y)	not both x and y	¬x ∨ ¬y	NAND
f8	f1000	1 0 0 0	x y	x and y	x ∧ y	Conjunction
f9	f1001	1 0 0 1	((x, y))	x equal to y	x = y	Equality
f10	f1010	1 0 1 0	y	y	y	Two
f11	f1011	1 0 1 1	(x (y))	not x without y	x → y	Implication
f12	f1100	1 1 0 0	x	x	x	One
f13	f1101	1 1 0 1	((x) y)	not y without x	x ← y	Involution
f14	f1110	1 1 1 0	((x)(y))	x or y	x ∨ y	Disjunction
f15	f1111	1 1 1 1	(( ))	true	1	Tautology

Truth Tables

Logical negation

Logical negation is an operation on one logical value, typically the value of a proposition, that produces a value of true when its operand is false and a value of false when its operand is true.

The truth table of NOT p (also written as ~p or ¬p) is as follows:

Logical Negation

p	¬p
F	T
T	F

The logical negation of a proposition p is notated in different ways in various contexts of discussion and fields of application. Among these variants are the following:

Variant Notations

Notation	Vocalization
\(\bar{p}\)	bar p
\(p'\!\)	p prime, p complement
\(!p\!\)	bang p

No matter how it is notated or symbolized, the logical negation ¬p is read as "it is not the case that p", or usually more simply as "not p".

• Within a system of classical logic, double negation, that is, the negation of the negation of a proposition p, is logically equivalent to the initial proposition p. Expressed in symbolic terms, ¬(¬p) ⇔ p.

• Within a system of intuitionistic logic, however, ¬¬p is a weaker statement than p. On the other hand, the logical equivalence ¬¬¬p ⇔ ¬p remains valid.

Logical negation can be defined in terms of other logical operations. For example, ~p can be defined as p → F, where → is material implication and F is absolute falsehood. Conversely, one can define F as p & ~p for any proposition p, where & is logical conjunction. The idea here is that any contradiction is false. While these ideas work in both classical and intuitionistic logic, they don't work in Brazilian logic, where contradictions are not necessarily false. But in classical logic, we get a further identity: p → q can be defined as ~p ∨ q, where ∨ is logical disjunction.

Algebraically, logical negation corresponds to the complement in a Boolean algebra (for classical logic) or a Heyting algebra (for intuitionistic logic).

Logical conjunction

Logical conjunction is an operation on two logical values, typically the values of two propositions, that produces a value of true if and only if both of its operands are true.

The truth table of p AND q (also written as p ∧ q, p & q, or p\(\cdot\)q) is as follows:

Logical Conjunction

p	q	p ∧ q
F	F	F
F	T	F
T	F	F
T	T	T

Logical disjunction

Logical disjunction is an operation on two logical values, typically the values of two propositions, that produces a value of false if and only if both of its operands are false.

The truth table of p OR q (also written as p ∨ q) is as follows:

Logical Disjunction

p	q	p ∨ q
F	F	F
F	T	T
T	F	T
T	T	T

Logical equality

Logical equality is an operation on two logical values, typically the values of two propositions, that produces a value of true if and only if both operands are false or both operands are true.

The truth table of p EQ q (also written as p = q, p ↔ q, or p ≡ q) is as follows:

Logical Equality

p	q	p = q
F	F	T
F	T	F
T	F	F
T	T	T

Exclusive disjunction

Exclusive disjunction is an operation on two logical values, typically the values of two propositions, that produces a value of true just in case exactly one of its operands is true.

The truth table of p XOR q (also written as p + q, p ⊕ q, or p ≠ q) is as follows:

Exclusive Disjunction

p	q	p XOR q
F	F	F
F	T	T
T	F	T
T	T	F

The following equivalents can then be deduced:

\[\begin{matrix} p + q & = & (p \land \lnot q) & \lor & (\lnot p \land q) \\ \\ & = & (p \lor q) & \land & (\lnot p \lor \lnot q) \\ \\ & = & (p \lor q) & \land & \lnot (p \land q) \end{matrix}\]

Generalized or n-ary XOR is true when the number of 1-bits is odd.

 A + B = (A ∧ !B) ∨ (!A ∧ B)
       = {(A ∧ !B) ∨ !A} ∧ {(A ∧ !B) ∨ B}
       = {(A ∨ !A) ∧ (!B ∨ !A)} ∧ {(A ∨ B) ∧ (!B ∨ B)}
       = (!A ∨ !B) ∧ (A ∨ B)
       = !(A ∧ B) ∧ (A ∨ B)

 p + q = (p ∧ !q)  ∨ (!p ∧ B)
 
       = {(p ∧ !q) ∨ !p} ∧ {(p ∧ !q) ∨ q}
 
       = {(p ∨ !q) ∧ (!q ∨ !p)} ∧ {(p ∨ q) ∧ (!q ∨ q)}
 
       = (!p ∨ !q) ∧ (p ∨ q)
 
       = !(p ∧ q)  ∧ (p ∨ q)

 p + q = (p ∧ ~q)  ∨ (~p ∧ q)
 
       = ((p ∧ ~q) ∨ ~p) ∧ ((p ∧ ~q) ∨ q)
 
       = ((p ∨ ~q) ∧ (~q ∨ ~p)) ∧ ((p ∨ q) ∧ (~q ∨ q))
 
       = (~p ∨ ~q) ∧ (p ∨ q)
 
       = ~(p ∧ q)  ∧ (p ∨ q)

\[\begin{matrix} p + q & = & (p \land \lnot q) & \lor & (\lnot p \land q) \\ & = & ((p \land \lnot q) \lor \lnot p) & \and & ((p \land \lnot q) \lor q) \\ & = & ((p \lor \lnot q) \land (\lnot q \lor \lnot p)) & \land & ((p \lor q) \land (\lnot q \lor q)) \\ & = & (\lnot p \lor \lnot q) & \land & (p \lor q) \\ & = & \lnot (p \land q) & \land & (p \lor q) \end{matrix}\]

Logical implication

The material conditional and logical implication are both associated with an operation on two logical values, typically the values of two propositions, that produces a value of false if and only if the first operand is true and the second operand is false.

The truth table associated with the material conditional if p then q (symbolized as p → q) and the logical implication p implies q (symbolized as p ⇒ q) is as follows:

Logical Implication

p	q	p ⇒ q
F	F	T
F	T	T
T	F	F
T	T	T

Logical NAND

The NAND operation is a logical operation on two logical values, typically the values of two propositions, that produces a value of false if and only if both of its operands are true. In other words, it produces a value of true if and only if at least one of its operands is false.

The truth table of p NAND q (also written as p | q or p ↑ q) is as follows:

Logical NAND

p	q	p ↑ q
F	F	T
F	T	T
T	F	T
T	T	F

Logical NNOR

The NNOR operation is a logical operation on two logical values, typically the values of two propositions, that produces a value of true if and only if both of its operands are false. In other words, it produces a value of false if and only if at least one of its operands is true.

The truth table of p NNOR q (also written as p ⊥ q or p ↓ q) is as follows:

Logical NOR

p	q	p ↓ q
F	F	T
F	T	F
T	F	F
T	T	F

Relational Tables

Sign Relations

	O	=	Object Domain
	S	=	Sign Domain
	I	=	Interpretant Domain

	O	=	{Ann, Bob}	=	{A, B}
	S	=	{"Ann", "Bob", "I", "You"}	=	{"A", "B", "i", "u"}
	I	=	{"Ann", "Bob", "I", "You"}	=	{"A", "B", "i", "u"}

L_A = Sign Relation of Interpreter A

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"i"
A	"i"	"A"
A	"i"	"i"
B	"B"	"B"
B	"B"	"u"
B	"u"	"B"
B	"u"	"u"

L_B = Sign Relation of Interpreter B

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"u"
A	"u"	"A"
A	"u"	"u"
B	"B"	"B"
B	"B"	"i"
B	"i"	"B"
B	"i"	"i"

Triadic Relations

Algebraic Examples

L₀ = {(x, y, z) ∈ B³ : x + y + z = 0}

X	Y	Z
0	0	0
0	1	1
1	0	1
1	1	0

L₁ = {(x, y, z) ∈ B³ : x + y + z = 1}

X	Y	Z
0	0	1
0	1	0
1	0	0
1	1	1

Semiotic Examples

L_A = Sign Relation of Interpreter A

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"i"
A	"i"	"A"
A	"i"	"i"
B	"B"	"B"
B	"B"	"u"
B	"u"	"B"
B	"u"	"u"

L_B = Sign Relation of Interpreter B

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"u"
A	"u"	"A"
A	"u"	"u"
B	"B"	"B"
B	"B"	"i"
B	"i"	"B"
B	"i"	"i"

Dyadic Projections

	LOS	=	projOS(L)	=	{ (o, s) ∈ O × S : (o, s, i) ∈ L for some i ∈ I }
	LSO	=	projSO(L)	=	{ (s, o) ∈ S × O : (o, s, i) ∈ L for some i ∈ I }
	LIS	=	projIS(L)	=	{ (i, s) ∈ I × S : (o, s, i) ∈ L for some o ∈ O }
	LSI	=	projSI(L)	=	{ (s, i) ∈ S × I : (o, s, i) ∈ L for some o ∈ O }
	LOI	=	projOI(L)	=	{ (o, i) ∈ O × I : (o, s, i) ∈ L for some s ∈ S }
	LIO	=	projIO(L)	=	{ (i, o) ∈ I × O : (o, s, i) ∈ L for some s ∈ S }

Method 1 : Subtitles as Captions

projOS(LA) Object Sign A "A" A "i" B "B" B "u"

projOS(LB) Object Sign A "A" A "u" B "B" B "i"

projSI(LA) Sign Interpretant "A" "A" "A" "i" "i" "A" "i" "i" "B" "B" "B" "u" "u" "B" "u" "u"

projSI(LB) Sign Interpretant "A" "A" "A" "u" "u" "A" "u" "u" "B" "B" "B" "i" "i" "B" "i" "i"

projOI(LA) Object Interpretant A "A" A "i" B "B" B "u"

projOI(LB) Object Interpretant A "A" A "u" B "B" B "i"

Method 2 : Subtitles as Top Rows

projOS(LA) Object Sign A "A" A "i" B "B" B "u"

projOS(LB) Object Sign A "A" A "u" B "B" B "i"

projSI(LA) Sign Interpretant "A" "A" "A" "i" "i" "A" "i" "i" "B" "B" "B" "u" "u" "B" "u" "u"

projSI(LB) Sign Interpretant "A" "A" "A" "u" "u" "A" "u" "u" "B" "B" "B" "i" "i" "B" "i" "i"

projOI(LA) Object Interpretant A "A" A "i" B "B" B "u"

projOI(LB) Object Interpretant A "A" A "u" B "B" B "i"

Relation Reduction

Method 1 : Subtitles as Captions

L₀ = {(x, y, z) ∈ B³ : x + y + z = 0}

X	Y	Z
0	0	0
0	1	1
1	0	1
1	1	0

L₁ = {(x, y, z) ∈ B³ : x + y + z = 1}

X	Y	Z
0	0	1
0	1	0
1	0	0
1	1	1

projXY(L0) X Y 0 0 0 1 1 0 1 1

projXZ(L0) X Z 0 0 0 1 1 1 1 0

projYZ(L0) Y Z 0 0 1 1 0 1 1 0

projXY(L1) X Y 0 0 0 1 1 0 1 1

projXZ(L1) X Z 0 1 0 0 1 0 1 1

projYZ(L1) Y Z 0 1 1 0 0 0 1 1

projXY(L0) = projXY(L1)

projXZ(L0) = projXZ(L1)

projYZ(L0) = projYZ(L1)

L_A = Sign Relation of Interpreter A

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"i"
A	"i"	"A"
A	"i"	"i"
B	"B"	"B"
B	"B"	"u"
B	"u"	"B"
B	"u"	"u"

L_B = Sign Relation of Interpreter B

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"u"
A	"u"	"A"
A	"u"	"u"
B	"B"	"B"
B	"B"	"i"
B	"i"	"B"
B	"i"	"i"

projXY(LA) Object Sign A "A" A "i" B "B" B "u"

projXZ(LA) Object Interpretant A "A" A "i" B "B" B "u"

projYZ(LA) Sign Interpretant "A" "A" "A" "i" "i" "A" "i" "i" "B" "B" "B" "u" "u" "B" "u" "u"

projXY(LB) Object Sign A "A" A "u" B "B" B "i"

projXZ(LB) Object Interpretant A "A" A "u" B "B" B "i"

projYZ(LB) Sign Interpretant "A" "A" "A" "u" "u" "A" "u" "u" "B" "B" "B" "i" "i" "B" "i" "i"

projXY(LA) ≠ projXY(LB)

projXZ(LA) ≠ projXZ(LB)

projYZ(LA) ≠ projYZ(LB)

Method 2 : Subtitles as Top Rows

L₀ = {(x, y, z) ∈ B³ : x + y + z = 0}

X	Y	Z
0	0	0
0	1	1
1	0	1
1	1	0

L₁ = {(x, y, z) ∈ B³ : x + y + z = 1}

X	Y	Z
0	0	1
0	1	0
1	0	0
1	1	1

projXY(L0) X Y 0 0 0 1 1 0 1 1

projXZ(L0) X Z 0 0 0 1 1 1 1 0

projYZ(L0) Y Z 0 0 1 1 0 1 1 0

projXY(L1) X Y 0 0 0 1 1 0 1 1

projXZ(L1) X Z 0 1 0 0 1 0 1 1

projYZ(L1) Y Z 0 1 1 0 0 0 1 1

projXY(L0) = projXY(L1)

projXZ(L0) = projXZ(L1)

projYZ(L0) = projYZ(L1)

L_A = Sign Relation of Interpreter A

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"i"
A	"i"	"A"
A	"i"	"i"
B	"B"	"B"
B	"B"	"u"
B	"u"	"B"
B	"u"	"u"

L_B = Sign Relation of Interpreter B

Object	Sign	Interpretant
A	"A"	"A"
A	"A"	"u"
A	"u"	"A"
A	"u"	"u"
B	"B"	"B"
B	"B"	"i"
B	"i"	"B"
B	"i"	"i"

projXY(LA) Object Sign A "A" A "i" B "B" B "u"

projXZ(LA) Object Interpretant A "A" A "i" B "B" B "u"

projYZ(LA) Sign Interpretant "A" "A" "A" "i" "i" "A" "i" "i" "B" "B" "B" "u" "u" "B" "u" "u"

projXY(LB) Object Sign A "A" A "u" B "B" B "i"

projXZ(LB) Object Interpretant A "A" A "u" B "B" B "i"

projYZ(LB) Sign Interpretant "A" "A" "A" "u" "u" "A" "u" "u" "B" "B" "B" "i" "i" "B" "i" "i"

projXY(LA) ≠ projXY(LB)

projXZ(LA) ≠ projXZ(LB)

projYZ(LA) ≠ projYZ(LB)

Formatted Text Display

So in a triadic fact, say, the example

A gives B to C

we make no distinction in the ordinary logic of relations between the subject nominative, the direct object, and the indirect object. We say that the proposition has three logical subjects. We regard it as a mere affair of English grammar that there are six ways of expressing this:

A gives B to C	A benefits C with B
B enriches C at expense of A	C receives B from A
C thanks A for B	B leaves A for C

These six sentences express one and the same indivisible phenomenon. (C.S. Peirce, "The Categories Defended", MS 308 (1903), EP 2, 170-171).

Work Area

Binary Operations

x0	x1	2f0	2f1	2f2	2f3	2f4	2f5	2f6	2f7	2f8	2f9	2f10	2f11	2f12	2f13	2f14	2f15
0	0	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1
1	0	0	0	1	1	0	0	1	1	0	0	1	1	0	0	1	1
0	1	0	0	0	0	1	1	1	1	0	0	0	0	1	1	1	1
1	1	0	0	0	0	0	0	0	0	1	1	1	1	1	1	1	1

Draft 1

TRUTH TABLES FOR THE BOOLEAN OPERATIONS OF ARITY UP TO 2

Constants 0f0 0f1 0 1

Unary Operations x0 1f0 1f1 1f2 1f3 0 0 1 0 1 1 0 0 1 1

Binary Operations x0 x1 2f0 2f1 2f2 2f3 2f4 2f5 2f6 2f7 2f8 2f9 2f10 2f11 2f12 2f13 2f14 2f15 0 0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 1 0 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1

Draft 2

TRUTH TABLES FOR THE BOOLEAN OPERATIONS OF ARITY UP TO 2

Constants 0f0 0f1 0 1

Unary Operations x0 1f0 1f1 1f2 1f3 0 0 1 0 1 1 0 0 1 1

Binary Operations x0 x1 2f0 2f1 2f2 2f3 2f4 2f5 2f6 2f7 2f8 2f9 2f10 2f11 2f12 2f13 2f14 2f15 0 0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 1 0 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1

Functional Quantifiers

Test Patterns

1	0	1	0	1	0	1	0
0	1	0	1	0	1	0	1

1	0	1	0	1	0	1	0
0	1	0	1	0	1	0	1

Table 1

Table 1. Qualifiers of Implication Ordering:  \(\alpha_i f = \Upsilon \langle f_i, f \rangle = \Upsilon \langle f_i \Rightarrow f \rangle\)

\(u:\) \(v:\)	1100 1010	\(f\!\)	\(\alpha_0\)	\(\alpha_1\)	\(\alpha_2\)	\(\alpha_3\)	\(\alpha_4\)	\(\alpha_5\)	\(\alpha_6\)	\(\alpha_7\)	\(\alpha_8\)	\(\alpha_9\)	\(\alpha_{10}\)	\(\alpha_{11}\)	\(\alpha_{12}\)	\(\alpha_{13}\)	\(\alpha_{14}\)	\(\alpha_{15}\)
\(f_0\)	0000	\((~)\)	1	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
\(f_1\)	0001	\((u)(v)\!\)	1	1	0	0	0	0	0	0	0	0	0	0	0	0	0	0
\(f_2\)	0010	\((u) v\!\)	1	0	1	0	0	0	0	0	0	0	0	0	0	0	0	0
\(f_3\)	0011	\((u)\!\)	1	1	1	1	0	0	0	0	0	0	0	0	0	0	0	0
\(f_4\)	0100	\(u (v)\!\)	1	0	0	0	1	0	0	0	0	0	0	0	0	0	0	0
\(f_5\)	0101	\((v)\!\)	1	1	0	0	1	1	0	0	0	0	0	0	0	0	0	0
\(f_6\)	0110	\((u, v)\!\)	1	0	1	0	1	0	1	0	0	0	0	0	0	0	0	0
\(f_7\)	0111	\((u v)\!\)	1	1	1	1	1	1	1	1	0	0	0	0	0	0	0	0
\(f_8\)	1000	\(u v\!\)	1	0	0	0	0	0	0	0	1	0	0	0	0	0	0	0
\(f_9\)	1001	\(((u, v))\!\)	1	1	0	0	0	0	0	0	1	1	0	0	0	0	0	0
\(f_{10}\)	1010	\(v\!\)	1	0	1	0	0	0	0	0	1	0	1	0	0	0	0	0
\(f_{11}\)	1011	\((u (v))\!\)	1	1	1	1	0	0	0	0	1	1	1	1	0	0	0	0
\(f_{12}\)	1100	\(u\!\)	1	0	0	0	1	0	0	0	1	0	0	0	1	0	0	0
\(f_{13}\)	1101	\(((u) v)\!\)	1	1	0	0	1	1	0	0	1	1	0	0	1	1	0	0
\(f_{14}\)	1110	\(((u)(v))\!\)	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0
\(f_{15}\)	1111	\(((~))\)	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1

Table 2

Table 2. Qualifiers of Implication Ordering:  \(\beta_i f = \Upsilon \langle f, f_i \rangle = \Upsilon \langle f \Rightarrow f_i \rangle\)

\(u:\) \(v:\)	1100 1010	\(f\!\)	\(\beta_0\)	\(\beta_1\)	\(\beta_2\)	\(\beta_3\)	\(\beta_4\)	\(\beta_5\)	\(\beta_6\)	\(\beta_7\)	\(\beta_8\)	\(\beta_9\)	\(\beta_{10}\)	\(\beta_{11}\)	\(\beta_{12}\)	\(\beta_{13}\)	\(\beta_{14}\)	\(\beta_{15}\)
\(f_0\)	0000	\((~)\)	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1
\(f_1\)	0001	\((u)(v)\!\)	0	1	0	1	0	1	0	1	0	1	0	1	0	1	0	1
\(f_2\)	0010	\((u) v\!\)	0	0	1	1	0	0	1	1	0	0	1	1	0	0	1	1
\(f_3\)	0011	\((u)\!\)	0	0	0	1	0	0	0	1	0	0	0	1	0	0	0	1
\(f_4\)	0100	\(u (v)\!\)	0	0	0	0	1	1	1	1	0	0	0	0	1	1	1	1
\(f_5\)	0101	\((v)\!\)	0	0	0	0	0	1	0	1	0	0	0	0	0	1	0	1
\(f_6\)	0110	\((u, v)\!\)	0	0	0	0	0	0	1	1	0	0	0	0	0	0	1	1
\(f_7\)	0111	\((u v)\!\)	0	0	0	0	0	0	0	1	0	0	0	0	0	0	0	1
\(f_8\)	1000	\(u v\!\)	0	0	0	0	0	0	0	0	1	1	1	1	1	1	1	1
\(f_9\)	1001	\(((u, v))\!\)	0	0	0	0	0	0	0	0	0	1	0	1	0	1	0	1
\(f_{10}\)	1010	\(v\!\)	0	0	0	0	0	0	0	0	0	0	1	1	0	0	1	1
\(f_{11}\)	1011	\((u (v))\!\)	0	0	0	0	0	0	0	0	0	0	0	1	0	0	0	1
\(f_{12}\)	1100	\(u\!\)	0	0	0	0	0	0	0	0	0	0	0	0	1	1	1	1
\(f_{13}\)	1101	\(((u) v)\!\)	0	0	0	0	0	0	0	0	0	0	0	0	0	1	0	1
\(f_{14}\)	1110	\(((u)(y))\!\)	0	0	0	0	0	0	0	0	0	0	0	0	0	0	1	1
\(f_{15}\)	1111	\(((~))\!\)	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	1

Table 3

Table 3. Simple Qualifiers of Propositions (n = 2)

\(u:\) \(v:\)	1100 1010	\(f\!\)	\((\ell_{11})\) \(\text{No } u \) \(\text{is } v \)	\((\ell_{10})\) \(\text{No } u \) \(\text{is }(v)\)	\((\ell_{01})\) \(\text{No }(u)\) \(\text{is } v \)	\((\ell_{00})\) \(\text{No }(u)\) \(\text{is }(v)\)	\( \ell_{00} \) \(\text{Some }(u)\) \(\text{is }(v)\)	\( \ell_{01} \) \(\text{Some }(u)\) \(\text{is } v \)	\( \ell_{10} \) \(\text{Some } u \) \(\text{is }(v)\)	\( \ell_{11} \) \(\text{Some } u \) \(\text{is } v \)
\(f_0\)	0000	\((~)\)	1	1	1	1
\(f_1\)	0001	\((u)(v)\!\)	1	1	1		1
\(f_2\)	0010	\((u) v\!\)	1	1		1		1
\(f_3\)	0011	\((u)\!\)	1	1			1	1
\(f_4\)	0100	\(u (v)\!\)	1		1	1			1
\(f_5\)	0101	\((v)\!\)	1		1		1		1
\(f_6\)	0110	\((u, v)\!\)	1			1		1	1
\(f_7\)	0111	\((u v)\!\)	1				1	1	1
\(f_8\)	1000	\(u v\!\)		1	1	1				1
\(f_9\)	1001	\(((u, v))\!\)		1	1		1			1
\(f_{10}\)	1010	\(v\!\)		1		1		1		1
\(f_{11}\)	1011	\((u (v))\!\)		1			1	1		1
\(f_{12}\)	1100	\(u\!\)			1	1			1	1
\(f_{13}\)	1101	\(((u) v)\!\)			1		1		1	1
\(f_{14}\)	1110	\(((u)(v))\!\)				1		1	1	1
\(f_{15}\)	1111	\(((~))\)					1	1	1	1

Table 4

Table 4. Simple Qualifiers of Propositions (n = 2)

\(u:\) \(v:\)	1100 1010	\(f\!\)	\((\ell_{11})\) \(\text{No } u \) \(\text{is } v \)	\((\ell_{10})\) \(\text{No } u \) \(\text{is }(v)\)	\((\ell_{01})\) \(\text{No }(u)\) \(\text{is } v \)	\((\ell_{00})\) \(\text{No }(u)\) \(\text{is }(v)\)	\( \ell_{00} \) \(\text{Some }(u)\) \(\text{is }(v)\)	\( \ell_{01} \) \(\text{Some }(u)\) \(\text{is } v \)	\( \ell_{10} \) \(\text{Some } u \) \(\text{is }(v)\)	\( \ell_{11} \) \(\text{Some } u \) \(\text{is } v \)
\(f_0\)	0000	\((~)\)	1	1	1	1
\(f_1\)	0001	\((u)(v)\!\)	1	1	1		1
\(f_2\)	0010	\((u) v\!\)	1	1		1		1
\(f_4\)	0100	\(u (v)\!\)	1		1	1			1
\(f_8\)	1000	\(u v\!\)		1	1	1				1
\(f_3\)	0011	\((u)\!\)	1	1			1	1
\(f_{12}\)	1100	\(u\!\)			1	1			1	1
\(f_6\)	0110	\((u, v)\!\)	1			1		1	1
\(f_9\)	1001	\(((u, v))\!\)		1	1		1			1
\(f_5\)	0101	\((v)\!\)	1		1		1		1
\(f_{10}\)	1010	\(v\!\)		1		1		1		1
\(f_7\)	0111	\((u v)\!\)	1				1	1	1
\(f_{11}\)	1011	\((u (v))\!\)		1			1	1		1
\(f_{13}\)	1101	\(((u) v)\!\)			1		1		1	1
\(f_{14}\)	1110	\(((u)(v))\!\)				1		1	1	1
\(f_{15}\)	1111	\(((~))\)					1	1	1	1

Table 5

Table 5. Relation of Quantifiers to Higher Order Propositions

\(\text{Mnemonic}\)	\(\text{Category}\)	\(\text{Classical Form}\)	\(\text{Alternate Form}\)	\(\text{Symmetric Form}\)	\(\text{Operator}\)
\(\text{E}\!\) \(\text{Exclusive}\)	\(\text{Universal}\) \(\text{Negative}\)	\(\text{All}\ u\ \text{is}\ (v)\)		\(\text{No}\ u\ \text{is}\ v \)	\((\ell_{11})\)
\(\text{A}\!\) \(\text{Absolute}\)	\(\text{Universal}\) \(\text{Affirmative}\)	\(\text{All}\ u\ \text{is}\ v \)		\(\text{No}\ u\ \text{is}\ (v)\)	\((\ell_{10})\)
		\(\text{All}\ v\ \text{is}\ u \)	\(\text{No}\ v\ \text{is}\ (u)\)	\(\text{No}\ (u)\ \text{is}\ v \)	\((\ell_{01})\)
		\(\text{All}\ (v)\ \text{is}\ u \)	\(\text{No}\ (v)\ \text{is}\ (u)\)	\(\text{No}\ (u)\ \text{is}\ (v)\)	\((\ell_{00})\)
		\(\text{Some}\ (u)\ \text{is}\ (v)\)		\(\text{Some}\ (u)\ \text{is}\ (v)\)	\(\ell_{00}\!\)
		\(\text{Some}\ (u)\ \text{is}\ v\)		\(\text{Some}\ (u)\ \text{is}\ v\)	\(\ell_{01}\!\)
\(\text{O}\!\) \(\text{Obtrusive}\)	\(\text{Particular}\) \(\text{Negative}\)	\(\text{Some}\ u\ \text{is}\ (v)\)		\(\text{Some}\ u\ \text{is}\ (v)\)	\(\ell_{10}\!\)
\(\text{I}\!\) \(\text{Indefinite}\)	\(\text{Particular}\) \(\text{Affirmative}\)	\(\text{Some}\ u\ \text{is}\ v\)		\(\text{Some}\ u\ \text{is}\ y\)	\(\ell_{11}\!\)