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	:: Coproducts 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,
	PARTFUN1, CARD_3, MSUALG_6, MSAFREE, TARSKI, MCART_1, ALTCAT_6;
	notations TARSKI, XBOOLE_0, XTUPLE_0, ORDINAL1, SUBSET_1, RELAT_1, FUNCT_1,
	RELSET_1, PARTFUN1, FUNCT_2, PBOOLE, CARD_3, FUNCOP_1, STRUCT_0,
	ALTCAT_1, ALTCAT_3, ALTCAT_5, MSAFREE;
	constructors ALTCAT_3, RELSET_1, ALTCAT_5, MSAFREE;
	registrations XBOOLE_0, RELSET_1, FUNCOP_1, STRUCT_0, ALTCAT_1, FUNCT_2,
	FUNCT_1, RELAT_1, ALTCAT_5, MSAFREE, XTUPLE_0;
	requirements SUBSET, BOOLE;
	definitions TARSKI, RELAT_1, FUNCT_1, FUNCOP_1, PBOOLE, FUNCT_2, ALTCAT_3;
	equalities TARSKI, ORDINAL1, CARD_3;
	expansions PARTFUN1;
	theorems FUNCT_2, FUNCOP_1, TARSKI, ALTCAT_1, FUNCT_5, FUNCT_1, ALTCAT_3,
	PARTFUN1, MSAFREE, XTUPLE_0, XBOOLE_0, SCMYCIEL, CARD_3, SUBSET_1;
	schemes PBOOLE, FUNCT_2, CLASSES1;

	begin

	reserve
	I for set,
	E for non empty set;

	set C = EnsCat {{}};

	Lm1: the carrier of C = {0} by ALTCAT_1:def 14;

	Lm2: Funcs({},{}) = {{}} 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;

	registration
	let I be non empty set;
	let A be ManySortedSet of I;
	let i be Element of I;
	cluster coprod(i,A) -> Relation-like Function-like;
	coherence
	proof
	set f = coprod(i,A);
	thus f is Relation-like
	proof
	let x be object;
	assume x in f;
	then ex a being set st a in A.i & x = [a,i] by MSAFREE:def 2;
	hence thesis;
	end;
	let x,y1,y2 be object;
	assume [x,y1] in f;
	then
	A1: ex a being set st a in A.i & [x,y1] = [a,i] by MSAFREE:def 2;
	assume [x,y2] in f;
	then ex b being set st b in A.i & [x,y2] = [b,i] by MSAFREE:def 2;
	then y1 = i & y2 = i by A1,XTUPLE_0:1;
	hence thesis;
	end;
	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 f,o -> ManySortedSet of I means
	:Def1:
	for i being object st i in I
	ex o1 being Object of C st o1 = f.i & it.i is Morphism of o1,o;
	existence
	proof
	defpred P[object,object] means ex o1 being Object of C st o1 = f.$1 &
	$2 is Morphism of o1,o;
	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 o1,o;
	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 f,o means
	:Def2:
	for i being Element of I holds it.i is Morphism of f.i,o;
	compatibility
	proof
	let F be ManySortedSet of I;
	hereby
	assume
	A1: F is MorphismsFamily of f,o;
	let i be Element of I;
	ex o1 being Object of C st o1 = f.i & F.i is Morphism of o1,o
	by A1,Def1;
	hence F.i is Morphism of f.i,o;
	end;
	assume
	A2: for i being Element of I holds F.i is Morphism of f.i,o;
	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 f,o;
	let i be Element of I;
	redefine func M.i -> Morphism of f.i,o;
	coherence by Def2;
	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 f,o;
	coherence
	proof
	let F be MorphismsFamily of f,o;
	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 o1,o by Def1;
	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 f,o
	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 f,o
	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 A,B;
	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 <^o,B^>;
	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 A,B;
	redefine attr P is feasible means :Def4:
	for i being Element of I holds P.i in <^A.i,B^>;
	compatibility
	proof
	thus P is feasible implies
	for i being Element of I holds P.i in <^A.i,B^>
	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 <^o,B^> by A1;
	hence thesis;
	end;
	assume
	A2: for i being Element of I holds P.i in <^A.i,B^>;
	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; :: coproduct Object
	let P be MorphismsFamily of A,B; :: coproductfamily
	attr P is coprojection-morphisms means
	for X being Object of C, F being MorphismsFamily of A,X
	st F is feasible
	ex f being Morphism of B,X st f in <^B,X^> &
	::existence
	(for i being set st i in I
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f * Pi) &
	::uniqueness
	for f1 being Morphism of B,X st for i being set st i in I
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f1 * Pi
	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 A,B;
	redefine attr P is coprojection-morphisms means
	for X being Object of C, F being MorphismsFamily of A,X st F is feasible
	ex f being Morphism of B,X st f in <^B,X^> &
	::existence
	(for i being Element of I holds F.i = f * P.i) &
	::uniqueness
	for f1 being Morphism of B,X st
	for i being Element of I holds F.i = f1 * P.i
	holds f = f1;
	correctness
	proof
	thus P is coprojection-morphisms implies
	for Y being Object of C, F being MorphismsFamily of A,Y st F is feasible
	ex f being Morphism of B,Y st f in <^B,Y^> &
	(for i being Element of I holds F.i = f * P.i) &
	for f1 being Morphism of B,Y st
	for i being Element of I holds F.i = f1 * P.i
	holds f = f1
	proof
	assume
	A1: P is coprojection-morphisms;
	let Y be Object of C, F be MorphismsFamily of A,Y;
	assume
	A2: F is feasible;
	consider f being Morphism of B,Y such that
	A3: f in <^B,Y^> and
	A4: for i being set st i in I
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f * Pi and
	A5: for f1 being Morphism of B,Y st for i being set st i in I
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f1 * Pi
	holds f = f1 by A2,A1;
	take f;
	thus f in <^B,Y^> by A3;
	hereby
	let i be Element of I;
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f * Pi by A4;
	hence F.i = f * P.i;
	end;
	let f1 be Morphism of B,Y such that
	A6: for i being Element of I holds F.i = f1 * P.i;
	for i being set st i in I
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f1 * Pi
	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 si,B;
	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 A,Y st F is feasible
	ex f being Morphism of B,Y st f in <^B,Y^> &
	(for i being Element of I holds F.i = f * P.i) &
	for f1 being Morphism of B,Y st
	for i being Element of I holds F.i = f1 * P.i
	holds f = f1;
	let Y be Object of C, F be MorphismsFamily of A,Y;
	assume F is feasible;
	then consider f be Morphism of B,Y such that
	A8: f in <^B,Y^> and
	A9: for i being Element of I holds F.i = f * P.i and
	A10: for f1 being Morphism of B,Y st
	for i being Element of I holds F.i = f1 * P.i
	holds f = f1 by A7;
	take f;
	thus f in <^B,Y^> by A8;
	thus for i being set st i in I
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f * Pi
	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 B,Y such that
	A11: for i being set st i in I
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f1 * Pi;
	now
	let i be Element of I;
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f1 * Pi by A11;
	hence F.i = f1 * P.i;
	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 A,B;
	coherence;
	end;

	theorem Th2:
	for C being category, A being ObjectsFamily of {},C
	for B being Object of C st B is initial holds
	ex P being MorphismsFamily of A,B st P is empty coprojection-morphisms
	proof
	let C be category;
	let A be ObjectsFamily of {},C;
	let B be Object of C;
	assume
	A1: B is initial;
	reconsider P = {} as MorphismsFamily of A,B by Th1;
	take P;
	thus P is empty;
	let X be Object of C, F be MorphismsFamily of A,X;
	assume F is feasible;
	consider f being Morphism of B,X such that
	A2: f in <^B,X^> &
	for M1 being Morphism of B,X st M1 in <^B,X^> holds f = M1
	by A1,ALTCAT_3:25;
	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 A,o
	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 A,o st P = I --> {} holds
	P is feasible coprojection-morphisms
	proof
	let A be ObjectsFamily of I,EnsCat {{}};
	let o be Object of EnsCat {{}};
	let P be MorphismsFamily of A,o;
	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 <^A.i,o^> by Lm3;
	hence thesis;
	end;
	let Y be Object of C, F being MorphismsFamily of A,Y;
	assume F is feasible;
	reconsider f = {} as Morphism of o,Y by Lm3;
	take f;
	thus f in <^o,Y^> by Lm3;
	thus for i being set st i in I
	ex si being Object of C, Pi being Morphism of si,o st
	si = A.i & Pi = P.i & F.i = f * Pi
	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 A1,Y;
	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 o,Y & f*M is Morphism of o,Y by Lm5;
	hence thesis by Lm6;
	end;
	thus thesis by Lm4;
	end;

	definition
	let C be category;
	attr C is with_coproducts means
	:Def7:
	for I being set, A being ObjectsFamily of I,C
	ex B being Object of C, P being MorphismsFamily of A,B st
	P is feasible coprojection-morphisms;
	end;

	registration
	cluster EnsCat {{}} -> with_coproducts;
	coherence
	proof
	let I be set, A be ObjectsFamily of I,C;
	reconsider o = {} as Object of C by Lm1,TARSKI:def 1;
	reconsider P = I --> {} as MorphismsFamily of A,o by Th3;
	take o,P;
	thus thesis by Th4;
	end;
	end;

	registration
	cluster with_products with_coproducts strict 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-CatCoproduct-like means
	ex P being MorphismsFamily of A,B st P is feasible coprojection-morphisms;
	end;

	registration
	let C be with_coproducts category;
	let I be set, A be ObjectsFamily of I,C;
	cluster A-CatCoproduct-like for Object of C;
	existence
	proof
	consider B being Object of C, P being MorphismsFamily of A,B such that
	A1: P is feasible coprojection-morphisms by Def7;
	take B,P;
	thus thesis by A1;
	end;
	end;

	registration
	let C be category;
	let A be ObjectsFamily of {},C;
	cluster A-CatCoproduct-like -> initial for Object of C;
	coherence
	proof
	let B be Object of C such that
	A1: B is A-CatCoproduct-like;
	for X being Object of C
	ex M being Morphism of B,X st M in <^B,X^> &
	for M1 being Morphism of B,X st M1 in <^B,X^> holds M = M1
	proof
	let X be Object of C;
	consider P being MorphismsFamily of A,B such that
	A2: P is feasible coprojection-morphisms by A1;
	set F = the MorphismsFamily of A,X;
	consider f being Morphism of B,X such that
	A3: f in <^B,X^> and
	for i being set st i in {}
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f * Pi and
	A4: for f1 being Morphism of B,X st for i being set st i in {}
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f1*Pi
	holds f = f1 by A2;
	take f;
	thus f in <^B,X^> by A3;
	let M be Morphism of B,X;
	for i being set st i in {}
	ex si being Object of C, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = M*Pi;
	hence thesis by A4;
	end;
	hence thesis by ALTCAT_3:25;
	end;
	end;

	theorem
	for C being category, A being ObjectsFamily of {},C
	for B being Object of C st B is initial holds
	B is A-CatCoproduct-like
	proof
	let C be category;
	let A be ObjectsFamily of {},C;
	let B be Object of C;
	assume B is initial;
	then ex P being MorphismsFamily of A,B st
	P is empty coprojection-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-CatCoproduct-like & C2 is A-CatCoproduct-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-CatCoproduct-like and
	A2: C2 is A-CatCoproduct-like;
	per cases;
	suppose I is empty;
	hence thesis by A1,A2,ALTCAT_3:26;
	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 A,C1 such that
	A3: P1 is feasible and
	A4: P1 is coprojection-morphisms by A1;
	consider P2 being MorphismsFamily of A,C2 such that
	A5: P2 is feasible and
	A6: P2 is coprojection-morphisms by A2;
	consider f1 being Morphism of C1,C2 such that
	A7: f1 in <^C1,C2^> and
	A8: for i being Element of I holds P2.i = f1*P1.i and
	for fa being Morphism of C1,C2 st
	for i being Element of I holds P2.i = fa*P1.i
	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 =g1* P1.i and
	A9: for fa being Morphism of C1,C1 st
	for i being Element of I holds P1.i = fa*P1.i
	holds g1 = fa by A3,A4;
	consider f2 being Morphism of C2,C1 such that
	A10: f2 in <^C2,C1^> and
	A11: for i being Element of I holds P1.i =f2* P2.i and
	for fa being Morphism of C2,C1 st
	for i being Element of I holds P1.i =fa* P2.i
	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 =g2* P2.i and
	A12: for fa being Morphism of C2,C2 st
	for i being Element of I holds P2.i = fa*P2.i
	holds fa = g2 by A5,A6;
	thus <^C1,C2^> <> {} & <^C2,C1^> <> {} by A7,A10;
	take f1;
	A13: f1 is retraction
	proof
	take f2;
	now
	let i be Element of I;
	P2.i in <^A.i,C2^> by A5;
	hence P2.i =idm C2 * P2.i by ALTCAT_1:20;
	end;
	then
	A14: g2 = idm C2 by A12;
	now
	let i be Element of I;
	P2.i in <^A.i,C2^> by A5;
	hence (f1 * f2)P2.i = f1 (f2 *P2.i) by A7,A10,ALTCAT_1:21
	.= f1 * P1.i by A11
	.= P2.i by A8;
	end;
	hence f1*f2 = idm C2 by A14,A12;
	end;
	f1 is coretraction
	proof
	take f2;
	now
	let i be Element of I;
	P1.i in <^A.i,C1^> by A3;
	hence P1.i = idm C1 *P1.i by ALTCAT_1:20;
	end;
	then
	A15: g1 = idm C1 by A9;
	now
	let i be Element of I;
	P1.i in <^A.i,C1^> by A3;
	hence (f2 * f1) P1.i = f2 (f1 *P1.i) by A7,A10,ALTCAT_1:21
	.= f2 * P2.i by A8
	.= P1.i by A11;
	end;
	hence f2 * f1 = 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: Union coprod A in E;
	func EnsCatCoproductObj A -> Object of EnsCat E equals :Def9:
	Union coprod A;
	coherence by A1,ALTCAT_1:def 14;
	end;

	definition
	let I,E,A;
	func Coprod(A) -> ManySortedSet of I means
	:Def10:
	for i being object st i in I
	ex F being Function of A.i,Union coprod A st
	it.i = F & for x being object st x in A.i holds F.x = [x,i];
	existence
	proof
	defpred P[object,object] means
	ex F being Function of A.$1,Union coprod A st
	$2 = F & for x being object st x in A.$1 holds F.x = [x,$1];
	A1: for i being object st i in I ex j being object st P[i,j]
	proof
	let i be object such that
	A2: i in I;
	defpred R[object,object] means $2 = [$1,i];
	A3: for x being object st x in A.i
	ex y being object st y in Union coprod A & R[x,y]
	proof
	let x be object such that
	A4: x in A.i;
	take y = [x,i];
	set Z = coprod(i,A);
	A5: y in Z by A2,A4,MSAFREE:def 2;
	A6: dom coprod A = I by PARTFUN1:def 2;
	(coprod A).i = Z by A2,MSAFREE:def 3;
	then Z in rng coprod A by A2,A6,FUNCT_1:3;
	hence y in Union coprod A by A5,TARSKI:def 4;
	thus R[x,y];
	end;
	ex F being Function of A.i,Union coprod A st
	for x being object st x in A.i holds R[x,F.x] from FUNCT_2:sch 1(A3);
	hence 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;
	uniqueness
	proof
	let X,Y be ManySortedSet of I such that
	A7: for i being object st i in I
	ex F being Function of A.i,Union coprod A st
	X.i = F & for x being object st x in A.i holds F.x = [x,i] and
	A8: for i being object st i in I
	ex F being Function of A.i,Union coprod A st
	Y.i = F & for x being object st x in A.i holds F.x = [x,i];
	let i be object such that
	A9: i in I;
	consider F being Function of A.i,Union coprod A such that
	A10: X.i = F and
	A11: for x being object st x in A.i holds F.x = [x,i] by A7,A9;
	consider G being Function of A.i,Union coprod A such that
	A12: Y.i = G and
	A13: for x being object st x in A.i holds G.x = [x,i] by A8,A9;
	per cases;
	suppose A.i is empty;
	then G = {} & F = {};
	hence thesis by A10,A12;
	end;
	suppose
	A14: A.i is non empty;
	F = G
	proof
	let x be Element of A.i;
	thus F.x = [x,i] by A11,A14
	.= G.x by A13,A14;
	end;
	hence thesis by A10,A12;
	end;
	end;
	end;

	registration
	let I,E,A;
	cluster Coprod(A) -> Function-yielding;
	coherence
	proof
	let i be object;
	assume i in dom Coprod(A);
	then ex F being Function of A.i,Union coprod A st Coprod(A).i = F &
	for x being object st x in A.i holds F.x = [x,i] by Def10;
	hence thesis;
	end;
	end;

	definition
	let I,E,A;
	assume
	A1: Union coprod A in E;
	func EnsCatCoproduct A -> MorphismsFamily of A,EnsCatCoproductObj A equals
	:Def11:
	Coprod A;
	coherence
	proof
	set P = Coprod A;
	set B = EnsCatCoproductObj A;
	A2: B = Union coprod A by A1,Def9;
	let i be object such that
	A3: i in I;
	consider F being Function of A.i,Union coprod A such that
	A4: P.i = F and
	for x being object st x in A.i holds F.x = [x,i] by A3,Def10;
	reconsider J = I as non empty set by A3;
	reconsider j = i as Element of J by A3;
	reconsider A1 = A as ObjectsFamily of J,EnsCat E;
	A5: <^A1.j,B^> = Funcs(A1.j,B) by ALTCAT_1:def 14;
	take o1 = A1.j;
	thus o1 = A.i;
	per cases;
	suppose B <> {};
	hence thesis by A2,A4,A5,FUNCT_2:8;
	end;
	suppose
	A6: B = {};
	then
	A7: P.i = {} by A4,A2;
	dom coprod A = I by PARTFUN1:def 2;
	then
	A8: (coprod A).i in rng coprod A by A3,FUNCT_1:3;
	rng coprod A = {} or rng coprod A = {{}} by A2,A6,SCMYCIEL:18;
	then (coprod A).i = {} by A8,TARSKI:def 1;
	then A.i = {} by A3,MSAFREE:2;
	hence thesis by A5,A7,A6,TARSKI:def 1,FUNCT_2:127;
	end;
	end;
	end;

	theorem Th7:
	Union coprod A = {} implies Coprod A is empty-yielding
	proof
	assume
	A1: Union coprod A = {};
	let i be object;
	assume i in I;
	then ex F being Function of A.i,Union coprod A st (Coprod A).i = F &
	for x being object st x in A.i holds F.x = [x,i] by Def10;
	hence thesis by A1;
	end;

	theorem Th8:
	Union coprod A = {} implies A is empty-yielding
	proof
	assume
	A1: Union coprod A = {};
	let i be object;
	assume i in I;
	then consider F being Function of A.i,Union coprod A such that
	(Coprod A).i = F and
	A2: for x being object st x in A.i holds F.x = [x,i] by Def10;
	assume A.i is non empty;
	then consider x being object such that
	A3: x in A.i by XBOOLE_0:7;
	F.x = [x,i] by A2,A3;
	hence thesis by A1;
	end;

	theorem
	Union coprod A in E & Union coprod A = {} implies
	EnsCatCoproduct A = I --> {}
	proof
	assume that
	A1: Union coprod A in E and
	A2: Union coprod A = {};
	let i be object;
	assume
	i in I;
	A4: Coprod A is empty-yielding by A2,Th7;
	thus (EnsCatCoproduct A).i = (Coprod A).i by A1,Def11
	.= {} by A4
	.= (I --> {}).i;
	end;

	theorem Th10:
	Union coprod A in E implies
	EnsCatCoproduct A is feasible coprojection-morphisms
	proof
	set B = EnsCatCoproductObj A;
	set P = EnsCatCoproduct A;
	assume
	A1: Union coprod A in E; then
	A2: B = Union coprod A by Def9;
	A3: P = Coprod A by A1,Def11;
	per cases;
	suppose
	A4: Union coprod A <> {};
	then
	A5: B <> {} by A1,Def9;
	thus
	A6: P is feasible
	proof
	let i be set;
	assume
	A7: i in I;
	then reconsider I as non empty set;
	reconsider i as Element of I by A7;
	reconsider A as ObjectsFamily of I,EnsCat E;
	reconsider P as MorphismsFamily of A,B;
	take A.i;
	A8: <^A.i,B^> = Funcs(A.i,B) by ALTCAT_1:def 14;
	Funcs(A.i,B) <> {} by A5;
	then P.i in <^A.i,B^> by A8;
	hence thesis;
	end;
	let X be Object of EnsCat E, F be MorphismsFamily of A,X;
	assume
	A9: F is feasible;
	A10: <^B,X^> = Funcs(B,X) by ALTCAT_1:def 14;
	defpred P[object,object] means
	$1`2 in I & $1`1 in A.$1`2 & $2 = F.$1`2.$1`1 &
	for j being object st j in I & $1 = [$1`1,j] holds F.j.$1`1 = $2;
	A11: for b being object st b in B ex u being object st P[b,u]
	proof
	let b be object;
	assume b in B;
	then consider Z being set such that
	A12: b in Z and
	A13: Z in rng coprod A by A2,TARSKI:def 4;
	consider i being object such that
	A14: i in dom coprod A and
	A15: (coprod A).i = Z by A13,FUNCT_1:def 3;
	(coprod A).i = coprod(i,A) by A14,MSAFREE:def 3;
	then consider x being set such that
	A16: x in A.i and
	A17: b = [x,i] by A12,A14,A15,MSAFREE:def 2;
	take F.i.x;
	thus b`2 in I & b`1 in A.b`2 & F.b`2.b`1 = F.i.x by A14,A16,A17;
	let j be object such that j in I and
	A18: b = [b`1,j];
	thus thesis by A17,A18,XTUPLE_0:1;
	end;
	consider ff being Function such that
	A19: dom ff = B and
	A20: for x being object st x in B holds P[x,ff.x] from CLASSES1:sch 1(A11);
	A21: rng ff c= X
	proof
	let y be object;
	assume y in rng ff;
	then consider x being object such that
	A22: x in dom ff and
	A23: ff.x = y by FUNCT_1:def 3;
	set i = x`2;
	A24: i in I by A19,A20,A22;
	A25: x`1 in A.i by A19,A20,A22;
	A26: ff.x = F.i.x`1 by A19,A20,A22;
	consider o1 being Object of EnsCat E such that
	A27: o1 = A.i and
	F.i is Morphism of o1,X by A24,Def1;
	A28: <^o1,X^> = Funcs(o1,X) by ALTCAT_1:def 14;
	then
	A29: X <> {} by A24,A25,A27,A9,Def4;
	F.i is Function of o1,X by A9,A24,A27,A28,Def4,FUNCT_2:66;
	hence thesis by A23,A25,A26,A27,A29,FUNCT_2:5;
	end;
	then reconsider ff as Morphism of B,X by A10,A19,FUNCT_2:def 2;
	take ff;
	thus
	A30: ff in <^B,X^> by A10,A21,A19,FUNCT_2:def 2;
	thus for i being set st i in I
	ex si being Object of EnsCat E, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = ff * Pi
	proof
	let i be set;
	assume
	A31: i in I;
	then reconsider I as non empty set;
	reconsider j = i as Element of I by A31;
	reconsider A1 = A as ObjectsFamily of I,EnsCat E;
	reconsider P1 = P as MorphismsFamily of A1,B;
	reconsider F1 = F as MorphismsFamily of A1,X;
	take A1.j,P1.j;
	thus A1.j = A.i & P1.j = P.i;
	reconsider p = P1.j as Function;
	A32: <^A1.j,B^> = Funcs(A1.j,B) by ALTCAT_1:def 14;
	A33: <^A1.j,B^> <> {} by A6,Def4;
	A34: <^A1.j,X^> = Funcs(A1.j,X) by ALTCAT_1:def 14;
	<^A1.j,X^> <> {} by A9,Def4; then
	A35: ff * P1.j = ff * p by A30,A33,ALTCAT_1:16;
	A36: F1.j in Funcs(A1.j,X) by A34,A9,Def4;
	then
	A37: dom(F1.j) = A1.j by FUNCT_2:92;
	A38: dom(ff*P1.j) = A1.j by A34,A36,FUNCT_2:92;
	A39: dom(P1.j) = A1.j by A32,A33,FUNCT_2:92;
	now
	let x be object;
	assume
	A40: x in dom(F1.j);
	p is Function of A1.j,B by A32,A6,Def4,FUNCT_2:66;
	then
	A41: p.x in B by A5,A37,A40,FUNCT_2:5;
	set x1 = (p.x)`1;
	ex C being Function of A.j,Union coprod A st
	P.i = C & for x being object st x in A.i holds C.x = [x,i]
	by A3,Def10;
	then
	A42: p.x = [x,j] by A37,A40;
	then ff.(p.x) = F.j.x1 by A41,A20;
	hence (ff*p).x = F1.j.x by A42,A37,A40,A39,FUNCT_1:13;
	end;
	hence F.i = ff * P1.j by A35,A38,A36,FUNCT_1:2,FUNCT_2:92;
	end;
	let f1 be Morphism of B,X such that
	A43: for i being set st i in I
	ex si being Object of EnsCat E, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f1 * Pi;
	per cases;
	suppose X = {};
	then f1 = {} & ff = {} by A5,A10,SUBSET_1:def 1;
	hence ff = f1;
	end;
	suppose
	A44: X <> {};
	f1 is Function of B,X by A10,A30,FUNCT_2:66;
	then
	A45: dom f1 = B by A44,FUNCT_2:def 1;
	now
	let x be object;
	assume
	A46: x in dom ff;
	set a = x`1;
	set i = x`2;
	A47: i in I by A19,A20,A46;
	then consider C being Function of A.i,Union coprod A such that
	A48: P.i = C and
	A49: for x being object st x in A.i holds C.x = [x,i] by A3,Def10;
	consider si being Object of EnsCat E, Pi being Morphism of si,B
	such that si = A.i and
	A50: Pi = P.i and
	A51: F.i = f1 * Pi by A43,A47;
	A52: a in A.i by A19,A20,A46;
	then
	A53: a in dom Pi by A48,A50,A4,FUNCT_2:def 1;
	A54: <^si,B^> = Funcs(si,B) by ALTCAT_1:def 14;
	<^si,X^> = Funcs(si,X) by ALTCAT_1:def 14;
	then
	A55: f1 * Pi = f1 qua Function * Pi by A2,A4,A44,A54,A10,ALTCAT_1:16;
	A56: ex y,z being object st x = [y,z] by A2,A19,A46,CARD_3:21;
	C.a = [a,i] by A49,A52;
	hence f1.x = F.i.a by A48,A50,A56,A51,A53,A55,FUNCT_1:13
	.= ff.x by A19,A20,A46;
	end;
	hence thesis by A19,A45,FUNCT_1:2;
	end;
	end;
	suppose
	A57: Union coprod A = {};
	thus P is feasible
	proof
	let i be set such that
	A58: i in I;
	reconsider I as non empty set by A58;
	reconsider i as Element of I by A58;
	reconsider A as ObjectsFamily of I,EnsCat E;
	take A.i;
	A59: Coprod A is empty-yielding by A57,Th7;
	A is empty-yielding by A57,Th8;
	then
	A60: A.i = {};
	A61: <^A.i,B^> = {{}} by A2,A57,A60,Lm2,ALTCAT_1:def 14;
	P.i = {} by A3,A59;
	hence thesis by A61,TARSKI:def 1;
	end;
	let X be Object of EnsCat E, F be MorphismsFamily of A,X;
	assume F is feasible;
	A62: <^B,X^> = Funcs(B,X) by ALTCAT_1:def 14
	.= {{}} by A2,A57,FUNCT_5:57;
	then reconsider f = {} as Morphism of B,X by TARSKI:def 1;
	take f;
	thus f in <^B,X^> by A62;
	thus for i being set st i in I
	ex si being Object of EnsCat E, Pi being Morphism of si,B st
	si = A.i & Pi = P.i & F.i = f * Pi
	proof
	let i be set such that
	A63: i in I;
	reconsider J = I as non empty set by A63;
	reconsider j = i as Element of J by A63;
	reconsider A1 = A as ObjectsFamily of J,EnsCat E;
	reconsider P1 = P as MorphismsFamily of A1,B;
	reconsider si = A1.j as Object of EnsCat E;
	reconsider Pi = P1.j as Morphism of si,B;
	reconsider F1 = F as MorphismsFamily of A1,X;
	reconsider F2 = F1.j as Morphism of si,X;
	take si, Pi;
	thus si = A.i & Pi = P.i;
	A64: A is empty-yielding by A57,Th8;
	then
	A65: si = {};
	then
	A66: <^si,B^> = {{}} by A2,A57,Lm2,ALTCAT_1:def 14;
	A67: <^si,X^> <> {} by A62,A64,A2,A57;
	A68: Funcs(si,X) = {{}} by A65,FUNCT_5:57;
	A69: <^si,X^> = Funcs(si,X) by ALTCAT_1:def 14;
	thus F.i = F2
	.= {} by A68,A69,TARSKI:def 1
	.= f qua Function * Pi
	.= f * Pi by A62,A66,A67,ALTCAT_1:16;
	end;
	thus thesis by A62,TARSKI:def 1;
	end;
	end;

	theorem
	Union coprod A in E implies EnsCatCoproductObj A is A-CatCoproduct-like
	proof
	assume
	A1: Union coprod A in E;
	take EnsCatCoproduct A;
	thus thesis by A1,Th10;
	end;

	theorem
	(for I,A holds Union coprod A in E) implies EnsCat E is with_coproducts
	proof
	assume
	A1: for I,A holds Union coprod A in E;
	let I,A;
	take EnsCatCoproductObj A, EnsCatCoproduct A;
	Union coprod A in E by A1;
	hence thesis by Th10;
	end;