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:: Products in Categories without Uniqueness of { \bf cod } and { \bf dom | |
:: } | |
:: http://creativecommons.org/licenses/by-sa/3.0/. | |
environ | |
vocabularies ALTCAT_1, CAT_1, RELAT_1, ALTCAT_3, CAT_3, FUNCT_1, PBOOLE, | |
ALTCAT_5, FUNCOP_1, CARD_1, FUNCT_2, XBOOLE_0, SUBSET_1, STRUCT_0, | |
TARSKI, PARTFUN1, CARD_3, MSUALG_6; | |
notations TARSKI, XBOOLE_0, SUBSET_1, RELAT_1, FUNCT_1, RELSET_1, PARTFUN1, | |
FUNCT_2, PBOOLE, CARD_3, FUNCOP_1, NUMBERS, STRUCT_0, ALTCAT_1, ALTCAT_3; | |
constructors ALTCAT_3, RELSET_1, CARD_3, NUMBERS; | |
registrations XBOOLE_0, RELSET_1, FUNCOP_1, STRUCT_0, ALTCAT_1, FUNCT_2, | |
FUNCT_1, CARD_3, RELAT_1; | |
requirements SUBSET, BOOLE; | |
definitions TARSKI, RELAT_1, FUNCOP_1, ALTCAT_3; | |
equalities ALTCAT_1, ORDINAL1; | |
expansions PARTFUN1; | |
theorems FUNCT_2, FUNCOP_1, CARD_1, TARSKI, ALTCAT_1, FUNCT_5, FUNCT_1, | |
ALTCAT_3, PARTFUN1, YELLOW17, RELAT_1, CARD_3, PBOOLE; | |
schemes PBOOLE, CLASSES1; | |
begin | |
reserve | |
I for set, | |
E for non empty set; | |
registration | |
cluster empty -> {}-defined for Relation; | |
coherence | |
proof | |
let R be Relation; | |
assume R is empty; | |
hence dom R c= {}; | |
end; | |
end; | |
definition | |
let C be AltGraph; | |
attr C is functional means | |
:Def1: | |
for a, b being Object of C holds <^a,b^> is functional; | |
end; | |
registration | |
let E; | |
cluster EnsCat E -> functional; | |
coherence | |
proof | |
let a, b be Object of EnsCat E; | |
<^a,b^> = Funcs(a,b) by ALTCAT_1:def 14; | |
hence thesis; | |
end; | |
end; | |
registration | |
cluster functional strict for category; | |
existence | |
proof | |
take EnsCat {{}}; | |
thus thesis; | |
end; | |
end; | |
registration | |
let C be functional AltCatStr; | |
cluster the AltGraph of C -> functional; | |
coherence | |
proof | |
let a,b be Object of the AltGraph of C; | |
reconsider a1 = a, b1 = b as Object of C; | |
<^a1,b1^> is functional by Def1; | |
hence thesis; | |
end; | |
end; | |
registration | |
cluster functional strict for AltGraph; | |
existence | |
proof | |
take the AltGraph of EnsCat {{}}; | |
thus thesis; | |
end; | |
end; | |
registration | |
cluster functional strict for category; | |
existence | |
proof | |
take EnsCat {{}}; | |
thus thesis; | |
end; | |
end; | |
registration | |
let C be functional AltGraph; | |
let a,b be Object of C; | |
cluster <^a,b^> -> functional; | |
coherence by Def1; | |
end; | |
reconsider a = 0, b = 1 as Element of 2 by CARD_1:50,TARSKI:def 2; | |
set C = EnsCat {{}}; | |
Lm1: the carrier of C = {0} by ALTCAT_1:def 14; | |
reconsider o = {} as Object of C by Lm1,TARSKI:def 1; | |
Lm2: Funcs({} qua set,{} qua set) = {{}} by FUNCT_5:57; | |
Lm3: | |
now | |
let o1,o be Object of C; | |
A1: o1 = {} & o = {} by Lm1,TARSKI:def 1; | |
<^o1,o^> = Funcs(o1,o) by ALTCAT_1:def 14; | |
hence {} is Morphism of o1,o & {} in <^o1,o^> by A1,Lm1,Lm2; | |
end; | |
Lm4: | |
now | |
let o1, o be Object of C; | |
let m1 be Morphism of o1,o; | |
A1: o = {} & o1 = {} by Lm1,TARSKI:def 1; | |
<^o1,o^> = Funcs(o1,o) by ALTCAT_1:def 14; | |
hence m1 = {} by A1,Lm2,TARSKI:def 1; | |
end; | |
Lm5: | |
now | |
let o1,o be Object of C; | |
o = {} & o1 = {} by Lm1,TARSKI:def 1; | |
hence o1 = o; | |
end; | |
Lm6: | |
now | |
let o1,o be Object of C; | |
let m1,m be Morphism of o1,o; | |
thus m1 = {} by Lm4 | |
.= m by Lm4; | |
end; | |
definition | |
let C be non empty AltCatStr; | |
let I be set; | |
mode ObjectsFamily of I,C is Function of I,C; | |
end; | |
definition | |
let C be non empty AltCatStr; | |
let o be Object of C; | |
let I be set; | |
let f be ObjectsFamily of I,C; | |
mode MorphismsFamily of o,f -> ManySortedSet of I means | |
:Def2: | |
for i being object st i in I | |
ex o1 being Object of C st o1 = f.i & it.i is Morphism of o,o1; | |
existence | |
proof | |
defpred P[object,object] means ex o1 being Object of C st o1 = f.$1 & | |
$2 is Morphism of o,o1; | |
A1: for i being object st i in I ex j being object st P[i,j] | |
proof | |
let i be object; | |
assume i in I; | |
then reconsider o1 = f.i as Object of C by FUNCT_2:5; | |
take the Morphism of o,o1; | |
thus thesis; | |
end; | |
ex f being ManySortedSet of I st | |
for i being object st i in I holds P[i,f.i] from PBOOLE:sch 3(A1); | |
hence thesis; | |
end; | |
end; | |
definition | |
let C be non empty AltCatStr; | |
let o be Object of C; | |
let I be non empty set; | |
let f be ObjectsFamily of I,C; | |
redefine mode MorphismsFamily of o,f means | |
:Def3: | |
for i being Element of I holds it.i is Morphism of o,f.i; | |
compatibility | |
proof | |
let F be ManySortedSet of I; | |
hereby | |
assume | |
A1: F is MorphismsFamily of o,f; | |
let i be Element of I; | |
ex o1 being Object of C st o1 = f.i & F.i is Morphism of o,o1 | |
by A1,Def2; | |
hence F.i is Morphism of o,f.i; | |
end; | |
assume | |
A2: for i being Element of I holds F.i is Morphism of o,f.i; | |
let i be object; | |
assume i in I; | |
then reconsider j = i as Element of I; | |
take f.j; | |
thus thesis by A2; | |
end; | |
end; | |
definition | |
let C be non empty AltCatStr; | |
let o be Object of C; | |
let I be non empty set; | |
let f be ObjectsFamily of I,C; | |
let M be MorphismsFamily of o,f; | |
let i be Element of I; | |
redefine func M.i -> Morphism of o,f.i; | |
coherence by Def3; | |
end; | |
registration | |
let C be functional non empty AltCatStr; | |
let o be Object of C; | |
let I be set; | |
let f be ObjectsFamily of I,C; | |
cluster -> Function-yielding for MorphismsFamily of o,f; | |
coherence | |
proof | |
let F be MorphismsFamily of o,f; | |
let i be object; | |
assume i in dom F; | |
then ex o1 being Object of C st | |
o1 = f.i & F.i is Morphism of o,o1 by Def2; | |
hence thesis; | |
end; | |
end; | |
theorem Th1: | |
for C being non empty AltCatStr, o being Object of C | |
for f being ObjectsFamily of {},C holds | |
{} is MorphismsFamily of o,f | |
proof | |
let C be non empty AltCatStr, o be Object of C, f be ObjectsFamily of {},C; | |
reconsider A = {} as {}-defined Relation; | |
A is total; | |
then reconsider A = {} as ManySortedSet of {}; | |
A is MorphismsFamily of o,f | |
proof | |
let i be object; | |
thus thesis; | |
end; | |
hence thesis; | |
end; | |
definition | |
let C be non empty AltCatStr; | |
let I be set; | |
let A be ObjectsFamily of I,C; | |
let B be Object of C; | |
let P be MorphismsFamily of B,A; | |
attr P is feasible means | |
for i being set st i in I ex o being Object of C st o = A.i & P.i in <^B,o^>; | |
end; | |
definition | |
let C be non empty AltCatStr; | |
let I be non empty set; | |
let A be ObjectsFamily of I,C; | |
let B be Object of C; | |
let P be MorphismsFamily of B,A; | |
redefine attr P is feasible means :Def5: | |
for i being Element of I holds P.i in <^B,A.i^>; | |
compatibility | |
proof | |
thus P is feasible implies | |
for i being Element of I holds P.i in <^B,A.i^> | |
proof | |
assume | |
A1: P is feasible; | |
let i be Element of I; | |
ex o being Object of C st o = A.i & P.i in <^B,o^> by A1; | |
hence thesis; | |
end; | |
assume | |
A2: for i being Element of I holds P.i in <^B,A.i^>; | |
let i be set; | |
assume i in I; | |
then reconsider i as Element of I; | |
reconsider A as ObjectsFamily of I,C; | |
take A.i; | |
thus thesis by A2; | |
end; | |
end; | |
definition | |
let C be category; | |
let I be set; | |
let A be ObjectsFamily of I,C; | |
let B be Object of C; :: product object | |
let P be MorphismsFamily of B,A; :: product family | |
attr P is projection-morphisms means | |
for X being Object of C, F being MorphismsFamily of X,A | |
st F is feasible | |
ex f being Morphism of X,B st f in <^X,B^> & | |
::existence | |
(for i being set st i in I | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f) & | |
::uniqueness | |
for f1 being Morphism of X,B st for i being set st i in I | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f1 | |
holds f = f1; | |
end; | |
definition | |
let C be category; | |
let I be non empty set; | |
let A be ObjectsFamily of I,C; | |
let B be Object of C; | |
let P be MorphismsFamily of B,A; | |
redefine attr P is projection-morphisms means | |
for X being Object of C, F being MorphismsFamily of X,A st F is feasible | |
ex f being Morphism of X,B st f in <^X,B^> & | |
::existence | |
(for i being Element of I holds F.i = P.i * f) & | |
::uniqueness | |
for f1 being Morphism of X,B st | |
for i being Element of I holds F.i = P.i * f1 | |
holds f = f1; | |
correctness | |
proof | |
thus P is projection-morphisms implies | |
for Y being Object of C, F being MorphismsFamily of Y,A st F is feasible | |
ex f being Morphism of Y,B st f in <^Y,B^> & | |
(for i being Element of I holds F.i = P.i * f) & | |
for f1 being Morphism of Y,B st | |
for i being Element of I holds F.i = P.i * f1 | |
holds f = f1 | |
proof | |
assume | |
A1: P is projection-morphisms; | |
let Y be Object of C, F be MorphismsFamily of Y,A; | |
assume | |
A2: F is feasible; | |
consider f being Morphism of Y,B such that | |
A3: f in <^Y,B^> and | |
A4: for i being set st i in I | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f and | |
A5: for f1 being Morphism of Y,B st for i being set st i in I | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f1 | |
holds f = f1 by A2,A1; | |
take f; | |
thus f in <^Y,B^> by A3; | |
hereby | |
let i be Element of I; | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f by A4; | |
hence F.i = P.i * f; | |
end; | |
let f1 be Morphism of Y,B such that | |
A6: for i being Element of I holds F.i = P.i * f1; | |
for i being set st i in I | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f1 | |
proof | |
let i be set; | |
assume i in I; | |
then reconsider i as Element of I; | |
reconsider si = A.i as Object of C; | |
reconsider Pi = P.i as Morphism of B,si; | |
take si, Pi; | |
thus thesis by A6; | |
end; | |
hence thesis by A5; | |
end; | |
assume | |
A7: for Y being Object of C, F being MorphismsFamily of Y,A st F is feasible | |
ex f being Morphism of Y,B st f in <^Y,B^> & | |
(for i being Element of I holds F.i = P.i * f) & | |
for f1 being Morphism of Y,B st | |
for i being Element of I holds F.i = P.i * f1 | |
holds f = f1; | |
let Y be Object of C, F be MorphismsFamily of Y,A; | |
assume F is feasible; | |
then consider f be Morphism of Y,B such that | |
A8: f in <^Y,B^> and | |
A9: for i being Element of I holds F.i = P.i * f and | |
A10: for f1 being Morphism of Y,B st | |
for i being Element of I holds F.i = P.i * f1 | |
holds f = f1 by A7; | |
take f; | |
thus f in <^Y,B^> by A8; | |
thus for i being set st i in I | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f | |
proof | |
let i be set; | |
assume i in I; | |
then reconsider j = i as Element of I; | |
take A.j, P.j; | |
thus thesis by A9; | |
end; | |
let f1 be Morphism of Y,B such that | |
A11: for i being set st i in I | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f1; | |
now | |
let i be Element of I; | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f1 by A11; | |
hence F.i = P.i * f1; | |
end; | |
hence thesis by A10; | |
end; | |
end; | |
registration | |
let C be category, A be ObjectsFamily of {},C; | |
let B be Object of C; | |
cluster -> feasible for MorphismsFamily of B,A; | |
coherence; | |
end; | |
theorem Th2: | |
for C being category, A being ObjectsFamily of {},C | |
for B being Object of C st B is terminal holds | |
ex P being MorphismsFamily of B,A st P is empty projection-morphisms | |
proof | |
let C be category; | |
let A be ObjectsFamily of {},C; | |
let B be Object of C; | |
assume | |
A1: B is terminal; | |
reconsider P = {} as MorphismsFamily of B,A by Th1; | |
take P; | |
thus P is empty; | |
let X be Object of C, F be MorphismsFamily of X,A; | |
assume F is feasible; | |
consider f being Morphism of X,B such that | |
A2: f in <^X,B^> & | |
for M1 being Morphism of X,B st M1 in <^X,B^> holds f = M1 | |
by A1,ALTCAT_3:27; | |
take f; | |
thus thesis by A2; | |
end; | |
theorem Th3: | |
for A being ObjectsFamily of I,EnsCat {{}}, o being Object of EnsCat {{}} | |
holds I --> {} is MorphismsFamily of o,A | |
proof | |
let A be ObjectsFamily of I,C; | |
let o be Object of C; | |
let i be object such that | |
A1: i in I; | |
reconsider I as non empty set by A1; | |
reconsider j = i as Element of I by A1; | |
reconsider A1 = A as ObjectsFamily of I,C; | |
reconsider o1 = A1.j as Object of C; | |
take o1; | |
thus o1 = A.i; | |
thus thesis by Lm3; | |
end; | |
theorem Th4: | |
for A being ObjectsFamily of I,EnsCat {{}}, | |
o being Object of EnsCat {{}}, | |
P being MorphismsFamily of o,A st P = I --> {} holds | |
P is feasible projection-morphisms | |
proof | |
let A be ObjectsFamily of I,EnsCat {{}}; | |
let o be Object of EnsCat {{}}; | |
let P be MorphismsFamily of o,A; | |
assume | |
A1: P = I --> {}; | |
thus P is feasible | |
proof | |
let i be set; | |
assume | |
A2: i in I; | |
then reconsider I as non empty set; | |
reconsider i as Element of I by A2; | |
reconsider A as ObjectsFamily of I,C; | |
P.i = {} by A1; | |
then P.i in <^o,A.i^> by Lm3; | |
hence thesis; | |
end; | |
let Y be Object of C, F being MorphismsFamily of Y,A; | |
assume F is feasible; | |
reconsider f = {} as Morphism of Y,o by Lm3; | |
take f; | |
thus f in <^Y,o^> by Lm3; | |
thus for i being set st i in I | |
ex si being Object of C, Pi being Morphism of o,si st | |
si = A.i & Pi = P.i & F.i = Pi * f | |
proof | |
let i be set; | |
assume | |
A3: i in I; | |
then reconsider I as non empty set; | |
reconsider j = i as Element of I by A3; | |
reconsider M = {} as Morphism of o,o by Lm3; | |
reconsider A1 = A as ObjectsFamily of I,C; | |
reconsider F1 = F as MorphismsFamily of Y,A1; | |
take o, M; | |
A1.j = {} by Lm1,TARSKI:def 1; | |
hence o = A.i by Lm5; | |
thus M = P.i by A1; | |
F1.j is Morphism of Y,o & M*f is Morphism of Y,o by Lm5; | |
hence thesis by Lm6; | |
end; | |
thus thesis by Lm4; | |
end; | |
definition | |
let C be category; | |
attr C is with_products means | |
:Def8: | |
for I being set, A being ObjectsFamily of I,C | |
ex B being Object of C, P being MorphismsFamily of B,A st | |
P is feasible projection-morphisms; | |
end; | |
registration | |
cluster EnsCat {{}} -> with_products; | |
coherence | |
proof | |
let I be set, A be ObjectsFamily of I,C; | |
reconsider P = I --> {} as MorphismsFamily of o,A by Th3; | |
take o,P; | |
thus thesis by Th4; | |
end; | |
end; | |
registration | |
cluster with_products for category; | |
existence | |
proof | |
take EnsCat {{}}; | |
thus thesis; | |
end; | |
end; | |
definition | |
let C be category; | |
let I be set, A be ObjectsFamily of I,C; | |
let B be Object of C; | |
attr B is A-CatProduct-like means | |
ex P being MorphismsFamily of B,A st P is feasible projection-morphisms; | |
end; | |
registration | |
let C be with_products category; | |
let I be set, A be ObjectsFamily of I,C; | |
cluster A-CatProduct-like for Object of C; | |
existence | |
proof | |
consider B being Object of C, P being MorphismsFamily of B,A such that | |
A1: P is feasible projection-morphisms by Def8; | |
take B,P; | |
thus thesis by A1; | |
end; | |
end; | |
registration | |
let C be category; | |
let A be ObjectsFamily of {},C; | |
cluster A-CatProduct-like -> terminal for Object of C; | |
coherence | |
proof | |
let B be Object of C such that | |
A1: B is A-CatProduct-like; | |
for X being Object of C | |
ex M being Morphism of X,B st M in <^X,B^> & | |
for M1 being Morphism of X,B st M1 in <^X,B^> holds M = M1 | |
proof | |
let X be Object of C; | |
consider P being MorphismsFamily of B,A such that | |
A2: P is feasible projection-morphisms by A1; | |
set F = the MorphismsFamily of X,A; | |
consider f being Morphism of X,B such that | |
A3: f in <^X,B^> and | |
for i being set st i in {} | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f and | |
A4: for f1 being Morphism of X,B st for i being set st i in {} | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f1 | |
holds f = f1 by A2; | |
take f; | |
thus f in <^X,B^> by A3; | |
let M be Morphism of X,B; | |
for i being set st i in {} | |
ex si being Object of C, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * M; | |
hence thesis by A4; | |
end; | |
hence thesis by ALTCAT_3:27; | |
end; | |
end; | |
theorem | |
for C being category, A being ObjectsFamily of {},C | |
for B being Object of C st B is terminal holds | |
B is A-CatProduct-like | |
proof | |
let C be category; | |
let A be ObjectsFamily of {},C; | |
let B be Object of C; | |
assume B is terminal; | |
then ex P being MorphismsFamily of B,A st | |
P is empty projection-morphisms by Th2; | |
hence thesis; | |
end; | |
theorem | |
for C being category, A being ObjectsFamily of I,C, | |
C1,C2 being Object of C | |
st C1 is A-CatProduct-like & C2 is A-CatProduct-like | |
holds C1,C2 are_iso | |
proof | |
let C be category; | |
let A be ObjectsFamily of I,C; | |
let C1,C2 be Object of C; | |
assume that | |
A1: C1 is A-CatProduct-like and | |
A2: C2 is A-CatProduct-like; | |
per cases; | |
suppose I is empty; | |
hence thesis by A1,A2,ALTCAT_3:28; | |
end; | |
suppose I is non empty; | |
then reconsider I as non empty set; | |
reconsider A as ObjectsFamily of I,C; | |
consider P1 being MorphismsFamily of C1,A such that | |
A3: P1 is feasible and | |
A4: P1 is projection-morphisms by A1; | |
consider P2 being MorphismsFamily of C2,A such that | |
A5: P2 is feasible and | |
A6: P2 is projection-morphisms by A2; | |
consider f1 being Morphism of C2,C1 such that | |
A7: f1 in <^C2,C1^> and | |
A8: for i being Element of I holds P2.i = P1.i * f1 and | |
for fa being Morphism of C2,C1 st | |
for i being Element of I holds P2.i = P1.i * fa | |
holds f1 = fa by A4,A5; | |
consider g1 being Morphism of C1,C1 such that | |
g1 in <^C1,C1^> and | |
for i being Element of I holds P1.i = P1.i * g1 and | |
A9: for fa being Morphism of C1,C1 st | |
for i being Element of I holds P1.i = P1.i * fa | |
holds g1 = fa by A3,A4; | |
consider f2 being Morphism of C1,C2 such that | |
A10: f2 in <^C1,C2^> and | |
A11: for i being Element of I holds P1.i = P2.i * f2 and | |
for fa being Morphism of C1,C2 st | |
for i being Element of I holds P1.i = P2.i * fa | |
holds f2 = fa by A3,A6; | |
consider g2 being Morphism of C2,C2 such that | |
g2 in <^C2,C2^> and | |
for i being Element of I holds P2.i = P2.i * g2 and | |
A12: for fa being Morphism of C2,C2 st | |
for i being Element of I holds P2.i = P2.i * fa | |
holds g2 = fa by A5,A6; | |
thus <^C1,C2^> <> {} & <^C2,C1^> <> {} by A7,A10; | |
take f2; | |
A13: f2 is retraction | |
proof | |
take f1; | |
now | |
let i be Element of I; | |
P2.i in <^C2,A.i^> by A5; | |
hence P2.i = P2.i * idm C2 by ALTCAT_1:def 17; | |
end; | |
then | |
A14: g2 = idm C2 by A12; | |
now | |
let i be Element of I; | |
P2.i in <^C2,A.i^> by A5; | |
hence P2.i * (f2 * f1) = P2.i * f2 * f1 by A7,A10,ALTCAT_1:21 | |
.= P1.i * f1 by A11 | |
.= P2.i by A8; | |
end; | |
hence f2 * f1 = idm C2 by A14,A12; | |
end; | |
f2 is coretraction | |
proof | |
take f1; | |
now | |
let i be Element of I; | |
P1.i in <^C1,A.i^> by A3; | |
hence P1.i = P1.i * idm C1 by ALTCAT_1:def 17; | |
end; | |
then | |
A15: g1 = idm C1 by A9; | |
now | |
let i be Element of I; | |
P1.i in <^C1,A.i^> by A3; | |
hence P1.i * (f1 * f2) = P1.i * f1 * f2 by A7,A10,ALTCAT_1:21 | |
.= P2.i * f2 by A8 | |
.= P1.i by A11; | |
end; | |
hence f1 * f2 = idm C1 by A15,A9; | |
end; | |
hence thesis by A7,A10,A13,ALTCAT_3:6; | |
end; | |
end; | |
reserve A for ObjectsFamily of I,EnsCat E; | |
definition | |
let I,E,A; | |
assume | |
A1: product A in E; | |
func EnsCatProductObj A -> Object of EnsCat E equals :Def10: | |
product A; | |
coherence by A1,ALTCAT_1:def 14; | |
end; | |
definition | |
let I,E,A; | |
assume | |
A1: product A in E; | |
func EnsCatProduct A -> MorphismsFamily of EnsCatProductObj A,A | |
means :Def11: | |
for i being set st i in I holds it.i = proj(A,i); | |
existence | |
proof | |
deffunc F(object) = proj(A,$1); | |
consider P being ManySortedSet of I such that | |
A2: for i being object st i in I holds P.i = F(i) from PBOOLE:sch 4; | |
set B = EnsCatProductObj A; | |
A3: B = product A by A1,Def10; | |
P is MorphismsFamily of B,A | |
proof | |
let i be object such that | |
A4: i in I; | |
reconsider I as non empty set by A4; | |
reconsider i as Element of I by A4; | |
reconsider A as ObjectsFamily of I,EnsCat E; | |
take A.i; | |
A5: <^B,A.i^> = Funcs(B,A.i) by ALTCAT_1:def 14; | |
dom A = I by PARTFUN1:def 2; | |
then | |
A6: rng proj(A,i) c= A.i by YELLOW17:3; | |
dom proj(A,i) = B by A3,PARTFUN1:def 2; | |
then proj(A,i) in Funcs(B,A.i) by A6,FUNCT_2:def 2; | |
hence thesis by A2,A5; | |
end; | |
then reconsider P as MorphismsFamily of B,A; | |
take P; | |
thus thesis by A2; | |
end; | |
uniqueness | |
proof | |
let f,g be MorphismsFamily of EnsCatProductObj A,A such that | |
A7: for i being set st i in I holds f.i = proj(A,i) and | |
A8: for i being set st i in I holds g.i = proj(A,i); | |
now | |
let i be object; | |
assume | |
A9: i in I; | |
hence f.i = proj(A,i) by A7 | |
.= g.i by A8,A9; | |
end; | |
hence thesis by PBOOLE:3; | |
end; | |
end; | |
theorem Th7: | |
product A in E & product A = {} implies EnsCatProduct A = I --> {} | |
proof | |
assume that | |
A1: product A in E and | |
A2: product A = {}; | |
now | |
let i be object; | |
assume | |
i in I; | |
hence (EnsCatProduct A).i = proj(A,i) by A1,Def11 | |
.= {} by A2 | |
.= (I --> {}).i; | |
end; | |
hence thesis by PBOOLE:3; | |
end; | |
theorem Th8: | |
product A in E implies EnsCatProduct A is feasible projection-morphisms | |
proof | |
set B = EnsCatProductObj A; | |
set P = EnsCatProduct A; | |
assume | |
A1: product A in E; then | |
A2: B = product A by Def10; | |
per cases; | |
suppose | |
A3: product A <> {}; | |
A4: dom A = I by PARTFUN1:def 2; | |
A5: now | |
let i be set; | |
assume i in I; | |
then A.i in rng A by A4,FUNCT_1:def 3; | |
hence A.i <> {} by A3,CARD_3:26; | |
end; | |
thus P is feasible | |
proof | |
let i be set; | |
assume | |
A6: i in I; | |
then reconsider I as non empty set; | |
reconsider i as Element of I by A6; | |
reconsider A as ObjectsFamily of I,EnsCat E; | |
reconsider P as MorphismsFamily of B,A; | |
take A.i; | |
A7: <^B,A.i^> = Funcs(B,A.i) by ALTCAT_1:def 14; | |
A.i <> {} by A5; | |
then Funcs(B,A.i) <> {}; | |
then P.i in <^B,A.i^> by A7; | |
hence thesis; | |
end; | |
let X be Object of EnsCat E, F be MorphismsFamily of X,A; | |
assume F is feasible; | |
A8: <^X,B^> = Funcs(X,B) by ALTCAT_1:def 14; | |
defpred P[object,object] means | |
ex M being ManySortedSet of I st | |
(for i being set st i in I holds M.i = F.i.$1) & $2 = M; | |
A9: for x being object st x in X ex u being object st P[x,u] | |
proof | |
let x be object; | |
assume x in X; | |
deffunc I(object) = F.$1.x; | |
consider f being ManySortedSet of I such that | |
A10: for i being object st i in I holds f.i = I(i) from PBOOLE:sch 4; | |
take f,f; | |
thus thesis by A10; | |
end; | |
consider ff being Function such that | |
A11: dom ff = X and | |
A12: for x being object st x in X holds P[x,ff.x] from CLASSES1:sch 1(A9); | |
A13: rng ff c= B | |
proof | |
let y be object; | |
assume y in rng ff; | |
then consider x being object such that | |
A14: x in dom ff and | |
A15: ff.x = y by FUNCT_1:def 3; | |
consider M being ManySortedSet of I such that | |
A16: for i being set st i in I holds M.i = F.i.x and | |
A17: ff.x = M by A11,A12,A14; | |
A18: dom M = I by PARTFUN1:def 2; | |
now | |
let i be object; | |
assume | |
A19: i in dom A; | |
then reconsider I as non empty set; | |
reconsider j = i as Element of I by A19; | |
reconsider A1 = A as ObjectsFamily of I,EnsCat E; | |
reconsider F1 = F as MorphismsFamily of X,A1; | |
A20: <^X,A1.j^> = Funcs(X,A1.j) by ALTCAT_1:def 14; | |
A1.j <> {} by A5; | |
then | |
A21: dom(F1.j) = X & rng(F1.j) c= A1.j by A20,FUNCT_2:92; | |
then | |
A22: F1.j.x in rng(F1.j) by A14,A11,FUNCT_1:def 3; | |
M.j = F.j.x by A16; | |
hence M.i in A.i by A22,A21; | |
end; | |
hence thesis by A2,A4,A15,A17,A18,CARD_3:9; | |
end; | |
then reconsider ff as Morphism of X,B by A8,A11,FUNCT_2:def 2; | |
take ff; | |
thus | |
A23: ff in <^X,B^> by A8,A13,A11,FUNCT_2:def 2; | |
thus for i being set st i in I | |
ex si being Object of EnsCat E, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * ff | |
proof | |
let i be set; | |
assume | |
A24: i in I; | |
then reconsider I as non empty set; | |
reconsider j = i as Element of I by A24; | |
reconsider A1 = A as ObjectsFamily of I,EnsCat E; | |
reconsider P1 = P as MorphismsFamily of B,A1; | |
reconsider F1 = F as MorphismsFamily of X,A1; | |
take A1.j; | |
take P1.j; | |
thus A1.j = A.i & P1.j = P.i; | |
reconsider p = P1.j as Function; | |
A25: <^B,A1.j^> = Funcs(B,A1.j) by ALTCAT_1:def 14; | |
A26: A1.j <> {} by A5; | |
then <^X,A1.j^> <> {} by A25,A23,ALTCAT_1:def 2; | |
then | |
A27: P1.j * ff = p * ff by A23,A26,A25,ALTCAT_1:16; | |
A28: <^X,A1.j^> = Funcs(X,A1.j) by ALTCAT_1:def 14; | |
then | |
A29: dom(P1.j*ff) = X by A26,FUNCT_2:92; | |
A30: dom(F1.j) = X by A26,A28,FUNCT_2:92; | |
now | |
let x be object; | |
assume | |
A31: x in dom(F1.j); | |
then consider M being ManySortedSet of I such that | |
A32: for i being set st i in I holds M.i = F.i.x and | |
A33: ff.x = M by A12,A30; | |
A34: dom proj(A,j) = B by A2,CARD_3:def 16; | |
A35: ff.x in rng ff by A11,A30,A31,FUNCT_1:def 3; | |
thus (p*ff).x = p.(ff.x) by A11,A30,A31,FUNCT_1:13 | |
.= proj(A,j).(ff.x) by A1,Def11 | |
.= M.j by A33,A34,A35,A13,CARD_3:def 16 | |
.= F1.j.x by A32; | |
end; | |
hence F.i = P1.j * ff by A27,A29,A26,A28,FUNCT_2:92,FUNCT_1:2; | |
end; | |
let f1 be Morphism of X,B such that | |
A36: for i being set st i in I | |
ex si being Object of EnsCat E, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f1; | |
A37: f1 is Function of X,B by A8,A23,FUNCT_2:66; | |
then | |
A38: dom f1 = X by A3,A2,FUNCT_2:def 1; | |
A39: rng f1 c= B by A37,RELAT_1:def 19; | |
now | |
let x be object; | |
assume | |
A40: x in dom ff; | |
then | |
A41: f1.x in rng f1 by A11,A38,FUNCT_1:def 3; | |
reconsider h = f1.x as Function by A2,A37; | |
consider M being ManySortedSet of I such that | |
A42: for i being set st i in I holds M.i = F.i.x and | |
A43: ff.x = M by A11,A12,A40; | |
A44: dom h = I by A2,A4,A41,A39,CARD_3:9; | |
now | |
let i be object; | |
assume | |
A45: i in dom M; | |
then consider si being Object of EnsCat E, Pi being Morphism of B,si | |
such that | |
A46: si = A.i & Pi = P.i and | |
A47: F.i = Pi * f1 by A36; | |
A48: P.i = proj(A,i) by A1,A45,Def11; | |
A49: dom proj(A,i) = B by A2,CARD_3:def 16; | |
A50: <^B,si^> = Funcs(B,si) by ALTCAT_1:def 14; | |
A51: si <> {} by A5,A45,A46; | |
then | |
A52: <^X,si^> <> {} by A50,A23,ALTCAT_1:def 2; | |
thus M.i = (Pi*f1).x by A47,A42,A45 | |
.= (Pi qua Function*f1).x by A50,A23,A51,A52,ALTCAT_1:16 | |
.= Pi.h by A38,A11,A40,FUNCT_1:13 | |
.= h.i by A39,A41,A46,A48,A49,CARD_3:def 16; | |
end; | |
hence ff.x = f1.x by A44,A43,FUNCT_1:2,PARTFUN1:def 2; | |
end; | |
hence thesis by A11,A38,FUNCT_1:2; | |
end; | |
suppose | |
A53: product A = {}; | |
thus P is feasible | |
proof | |
let i be set such that | |
A54: i in I; | |
reconsider I as non empty set by A54; | |
reconsider i as Element of I by A54; | |
reconsider A as ObjectsFamily of I,EnsCat E; | |
take A.i; | |
A55: <^B,A.i^> = Funcs(B,A.i) by ALTCAT_1:def 14 | |
.= {{}} by A2,A53,FUNCT_5:57; | |
P.i = (I-->{}).i by A1,A53,Th7 | |
.= {}; | |
hence thesis by A55,TARSKI:def 1; | |
end; | |
let X be Object of EnsCat E, F be MorphismsFamily of X,A; | |
assume | |
A56: F is feasible; | |
A57: now | |
assume | |
A58: X <> {}; | |
{} in rng A by A53,CARD_3:26; | |
then consider i being object such that | |
A59: i in dom A and | |
A60: A.i = {} by FUNCT_1:def 3; | |
reconsider I as non empty set by A59; | |
reconsider i as Element of I by A59; | |
reconsider A as ObjectsFamily of I,EnsCat E; | |
<^X,A.i^> = Funcs(X,A.i) by ALTCAT_1:def 14 | |
.= {} by A58,A60; | |
hence contradiction by A56,Def5; | |
end; | |
A61: <^X,B^> = Funcs(X,B) by ALTCAT_1:def 14 | |
.= {{}} by A57,FUNCT_5:57; | |
then reconsider f = {} as Morphism of X,B by TARSKI:def 1; | |
take f; | |
thus f in <^X,B^> by A61; | |
thus for i being set st i in I | |
ex si being Object of EnsCat E, Pi being Morphism of B,si st | |
si = A.i & Pi = P.i & F.i = Pi * f | |
proof | |
let i be set such that | |
A62: i in I; | |
reconsider J = I as non empty set by A62; | |
reconsider j = i as Element of J by A62; | |
reconsider A1 = A as ObjectsFamily of J,EnsCat E; | |
reconsider P1 = P as MorphismsFamily of B,A1; | |
reconsider si = A1.j as Object of EnsCat E; | |
reconsider Pi = P1.j as Morphism of B,si; | |
reconsider F1 = F as MorphismsFamily of X,A1; | |
reconsider F2 = F1.j as Morphism of X,si; | |
take si, Pi; | |
thus si = A.i & Pi = P.i; | |
A63: <^B,si^> = Funcs(B,si) by ALTCAT_1:def 14 | |
.= {{}} by A2,A53,FUNCT_5:57; | |
then | |
A64: <^X,si^> <> {} by A61,ALTCAT_1:def 2; | |
A65: Funcs(X,si) = {{}} by A57,FUNCT_5:57; | |
A66: <^X,si^> = Funcs(X,si) by ALTCAT_1:def 14; | |
thus F.i = F2 | |
.= {} by A65,A66,TARSKI:def 1 | |
.= Pi qua Function * f | |
.= Pi * f by A63,A61,A64,ALTCAT_1:16; | |
end; | |
let f1 be Morphism of X,B; | |
thus thesis by A61,TARSKI:def 1; | |
end; | |
end; | |
theorem | |
product A in E implies EnsCatProductObj A is A-CatProduct-like | |
proof | |
assume | |
A1: product A in E; | |
take EnsCatProduct A; | |
thus thesis by A1,Th8; | |
end; | |
theorem | |
(for I,A holds product A in E) implies EnsCat E is with_products | |
proof | |
assume | |
A1: for I,A holds product A in E; | |
let I,A; | |
take EnsCatProductObj A, EnsCatProduct A; | |
product A in E by A1; | |
hence thesis by Th8; | |
end; | |