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proof-pile

	:: Homomorphisms of algebras. Quotient Universal Algebra
	:: by Ma{\l}gorzata Korolkiewicz

	environ

	vocabularies UNIALG_1, SUBSET_1, NUMBERS, UNIALG_2, XBOOLE_0, FINSEQ_1,
	FUNCT_1, RELAT_1, NAT_1, TARSKI, STRUCT_0, PARTFUN1, MSUALG_3, CQC_SIM1,
	WELLORD1, FINSEQ_2, GROUP_6, EQREL_1, FUNCT_2, CARD_3, RELAT_2, ALG_1;
	notations TARSKI, XBOOLE_0, SUBSET_1, ORDINAL1, NUMBERS, NAT_1, RELAT_1,
	RELAT_2, FUNCT_1, RELSET_1, PARTFUN1, FINSEQ_1, EQREL_1, FINSEQ_2,
	FUNCT_2, STRUCT_0, MARGREL1, UNIALG_1, FINSEQOP, FINSEQ_3, UNIALG_2;
	constructors EQREL_1, FINSEQOP, UNIALG_2, RELSET_1, CARD_3, FINSEQ_3, CARD_1,
	NAT_1, NUMBERS;
	registrations RELAT_1, FUNCT_1, PARTFUN1, FUNCT_2, EQREL_1, FINSEQ_2,
	STRUCT_0, UNIALG_1, UNIALG_2, ORDINAL1, FINSEQ_1, CARD_1, RELSET_1,
	MARGREL1;
	requirements BOOLE, SUBSET;
	definitions UNIALG_2, RELAT_2, TARSKI, FUNCT_1, XBOOLE_0, FUNCT_2, MARGREL1;
	equalities UNIALG_2, XBOOLE_0;
	expansions UNIALG_2, FUNCT_1, FUNCT_2, MARGREL1;
	theorems FINSEQ_1, FINSEQ_2, FUNCT_1, FUNCT_2, PARTFUN1, UNIALG_1, UNIALG_2,
	RELAT_1, RELSET_1, EQREL_1, ZFMISC_1, FINSEQ_3, XBOOLE_0, RELAT_2,
	ORDERS_1, MARGREL1;
	schemes FINSEQ_1, RELSET_1, FUNCT_2, FUNCT_1;

	begin

	reserve U1,U2,U3 for Universal_Algebra,
	n,m for Nat,
	o1 for operation of U1,
	o2 for operation of U2,
	o3 for operation of U3,
	x,y for set;

	theorem Th1:
	for B be non empty Subset of U1 st B = the carrier of U1 holds
	Opers(U1,B) = the charact of(U1)
	proof
	let B be non empty Subset of U1;
	A1: dom Opers(U1,B) = dom the charact of(U1) by UNIALG_2:def 6;
	assume
	A2: B = the carrier of U1;
	now
	let n be Nat;
	assume
	A3: n in dom the charact of(U1);
	then reconsider o = (the charact of U1).n as operation of U1 by
	FUNCT_1:def 3;
	thus Opers(U1,B).n = o/.B by A1,A3,UNIALG_2:def 6
	.= (the charact of U1).n by A2,UNIALG_2:4;
	end;
	hence thesis by A1;
	end;

	reserve a for FinSequence of U1,
	f for Function of U1,U2;

	theorem
	f(<>the carrier of U1) = <*>the carrier of U2;

	theorem Th3:
	(id the carrier of U1)*a = a
	proof
	set f = id the carrier of U1;
	A1: dom (f*a) = dom a by FINSEQ_3:120;
	A2: now
	let n be Nat;
	assume
	A3: n in dom(f*a);
	then reconsider u = a.n as Element of U1 by A1,FINSEQ_2:11;
	f.u = u;
	hence (f*a).n = a.n by A3,FINSEQ_3:120;
	end;
	len (f*a) = len a by FINSEQ_3:120;
	hence thesis by A2,FINSEQ_2:9;
	end;

	theorem Th4:
	for h1 be Function of U1,U2, h2 be Function of U2,U3,a be
	FinSequence of U1 holds h2(h1a) = (h2 * h1)*a
	proof
	let h1 be Function of U1,U2, h2 be Function of U2,U3,a be FinSequence of U1;
	A1: dom a = Seg len a by FINSEQ_1:def 3;
	A2: dom (h2(h1a)) = dom(h1*a) by FINSEQ_3:120;
	dom (h1*a) = dom a by FINSEQ_3:120;
	then
	A3: dom (h2(h1a)) = Seg len a by A2,FINSEQ_1:def 3;
	A4: len a = len((h2 * h1 qua Function of the carrier of U1, the carrier of
	U3) *(a qua FinSequence of the carrier of U1)) by FINSEQ_3:120;
	then
	A5: dom ((h2 * h1)*a) = Seg len a by FINSEQ_1:def 3;
	A6: now
	let n be Nat;
	assume
	A7: n in dom(h2(h1a));
	hence (h2(h1a)).n = h2.((h1*a).n) by FINSEQ_3:120
	.= h2.(h1.(a.n)) by A2,A7,FINSEQ_3:120
	.= (h2*h1).(a.n) by A1,A3,A7,FINSEQ_2:11,FUNCT_2:15
	.= ((h2 * h1)*a).n by A3,A5,A7,FINSEQ_3:120;
	end;
	len(h2(h1a)) = len(h1a) & len(h1a) = len a by FINSEQ_3:120;
	hence thesis by A4,A6,FINSEQ_2:9;
	end;

	definition
	let U1,U2,f;
	pred f is_homomorphism means
	U1,U2 are_similar &
	for n st n in dom the charact of(U1)
	for o1,o2 st o1=(the charact of U1).n &
	o2=(the charact of U2).n
	for x be FinSequence of U1 st x in dom o1 holds f.(o1.x) = o2.(f*x);
	end;

	definition
	let U1,U2,f;
	pred f is_monomorphism means
	f is_homomorphism & f is one-to-one;
	pred f is_epimorphism means
	f is_homomorphism & rng f = the carrier of U2;
	end;

	definition
	let U1,U2,f;
	pred f is_isomorphism means
	f is_monomorphism & f is_epimorphism;
	end;

	definition
	let U1,U2;
	pred U1,U2 are_isomorphic means
	ex f st f is_isomorphism;
	end;

	theorem Th5:
	id the carrier of U1 is_homomorphism
	proof
	thus U1,U1 are_similar;
	let n;
	assume n in dom the charact of(U1);
	let o1,o2 be operation of U1;
	assume
	A1: o1=(the charact of U1).n & o2=(the charact of U1).n;
	set f = id the carrier of U1;
	let x be FinSequence of U1;
	assume x in dom o1;
	then o1.x in rng o1 by FUNCT_1:def 3;
	then reconsider u = o1.x as Element of U1;
	f.u = u;
	hence thesis by A1,Th3;
	end;

	theorem Th6:
	for h1 be Function of U1,U2, h2 be Function of U2,U3 st h1
	is_homomorphism & h2 is_homomorphism holds h2 * h1 is_homomorphism
	proof
	let h1 be Function of U1,U2, h2 be Function of U2,U3;
	set s1 = signature U1, s2 = signature U2, s3 = signature U3;
	assume that
	A1: h1 is_homomorphism and
	A2: h2 is_homomorphism;
	U1,U2 are_similar by A1;
	then
	A3: s1 = s2;
	U2,U3 are_similar by A2;
	hence s1 = s3 by A3;
	let n;
	assume
	A4: n in dom the charact of(U1);
	let o1,o3;
	assume that
	A5: o1=(the charact of U1).n and
	A6: o3=(the charact of U3).n;
	let a;
	reconsider b = h1a as Element of (the carrier of U2) by FINSEQ_1:def 11;
	assume
	A7: a in dom o1;
	then
	A8: o1.a in rng o1 by FUNCT_1:def 3;
	dom o1 = (arity o1)-tuples_on (the carrier of U1) by MARGREL1:22;
	then a in {w where w is Element of (the carrier of U1)*: len w = arity o1}
	by A7,FINSEQ_2:def 4;
	then
	A9: ex w be Element of (the carrier of U1)* st w = a & len w = arity o1;
	A10: len s1 = len the charact of(U1) & dom the charact of(U1) = Seg len the
	charact of(U1) by FINSEQ_1:def 3,UNIALG_1:def 4;
	A11: len s2 = len the charact of(U2) & dom the charact of(U2) = Seg len the
	charact of(U2) by FINSEQ_1:def 3,UNIALG_1:def 4;
	then reconsider o2 = (the charact of U2).n as operation of U2 by A3,A10,A4,
	FUNCT_1:def 3;
	A12: dom s1 = Seg len s1 by FINSEQ_1:def 3;
	then
	A13: s2.n = arity o2 by A3,A10,A4,UNIALG_1:def 4;
	s1.n = arity o1 by A10,A12,A4,A5,UNIALG_1:def 4;
	then len(h1*a) = arity o2 by A3,A13,A9,FINSEQ_3:120;
	then dom o2 = (arity o2)-tuples_on (the carrier of U2) & b in {s where s is
	Element of (the carrier of U2)*: len s = arity o2} by MARGREL1:22;
	then h1*a in dom o2 by FINSEQ_2:def 4;
	then
	A14: h2.(o2.(h1a)) = o3.(h2(h1*a)) by A2,A3,A10,A11,A4,A6;
	h1.(o1.a) = o2.(h1*a) by A1,A4,A5,A7;
	hence (h2 * h1).(o1.a) = o3.(h2(h1a)) by A8,A14,FUNCT_2:15
	.= o3.((h2 * h1)*a) by Th4;
	end;

	theorem Th7:
	f is_isomorphism iff f is_homomorphism & rng f = the
	carrier of U2 & f is one-to-one
	proof
	thus f is_isomorphism implies f is_homomorphism & rng f = the
	carrier of U2 & f is one-to-one
	proof
	assume f is_isomorphism;
	then f is_monomorphism & f is_epimorphism;
	hence thesis;
	end;
	assume f is_homomorphism & rng f = the carrier of U2 & f is one-to-one;
	then f is_monomorphism & f is_epimorphism;
	hence thesis;
	end;

	theorem Th8:
	f is_isomorphism implies dom f = the carrier of U1 & rng f
	= the carrier of U2
	proof
	assume f is_isomorphism;
	then f is_epimorphism;
	hence thesis by FUNCT_2:def 1;
	end;

	theorem Th9:
	for h be Function of U1,U2, h1 be Function of U2,U1 st h
	is_isomorphism & h1=h" holds h1 is_homomorphism
	proof
	let h be Function of U1,U2,h1 be Function of U2,U1;
	assume that
	A1: h is_isomorphism and
	A2: h1=h";
	A3: h is one-to-one by A1,Th7;
	A4: h is_homomorphism by A1,Th7;
	then
	A5: U1,U2 are_similar;
	then
	A6: signature U1 = signature U2;
	A7: len (signature U1) = len the charact of(U1) & dom the charact of(U1) =
	Seg len the charact of(U1) by FINSEQ_1:def 3,UNIALG_1:def 4;
	A8: dom (signature U2) = Seg len (signature U2) by FINSEQ_1:def 3;
	A9: len (signature U2) = len the charact of(U2) & dom the charact of(U2) =
	Seg len the charact of(U2) by FINSEQ_1:def 3,UNIALG_1:def 4;
	A10: rng h = the carrier of U2 by A1,Th7;
	now
	let n;
	assume
	A11: n in dom the charact of(U2);
	let o2,o1;
	assume
	A12: o2 = (the charact of U2).n & o1 = (the charact of U1).n;
	let x be FinSequence of U2;
	defpred P[set,set] means h.$2 = x.$1;
	A13: dom x = Seg len x by FINSEQ_1:def 3;
	A14: for m be Nat st m in Seg len x ex a being Element of U1 st P[m,a]
	proof
	let m be Nat;
	assume m in Seg len x;
	then m in dom x by FINSEQ_1:def 3;
	then x.m in the carrier of U2 by FINSEQ_2:11;
	then consider a be object such that
	A15: a in dom h and
	A16: h.a = x.m by A10,FUNCT_1:def 3;
	reconsider a as Element of U1 by A15;
	take a;
	thus thesis by A16;
	end;
	consider p being FinSequence of U1 such that
	A17: dom p = Seg len x & for m be Nat st m in Seg len x holds P[m,p.m]
	from FINSEQ_1:sch 5(A14);
	A18: dom (h*p) = dom p by FINSEQ_3:120;
	now
	let n be Nat;
	assume
	A19: n in dom x;
	hence x.n = h.(p.n) by A17,A13
	.= (h*p).n by A17,A13,A18,A19,FINSEQ_3:120;
	end;
	then
	A20: x = h*p by A17,A13,A18;
	A21: len p = len x by A17,FINSEQ_1:def 3;
	assume x in dom o2;
	then x in (arity o2)-tuples_on the carrier of U2 by MARGREL1:22;
	then x in {s where s is Element of (the carrier of U2)*: len s = arity o2
	} by FINSEQ_2:def 4;
	then
	A22: ex s be Element of (the carrier of U2)* st x=s & len s = arity o2;
	A23: (h1 * h) = (id dom h) by A2,A3,FUNCT_1:39
	.= id the carrier of U1 by FUNCT_2:def 1;
	then
	A24: h1x = (id the carrier of U1)p by A20,Th4
	.=p by Th3;
	reconsider p as Element of (the carrier of U1)* by FINSEQ_1:def 11;
	(signature U1).n = arity o1 & (signature U2).n = arity o2 by A6,A8,A9,A11
	,A12,UNIALG_1:def 4;
	then
	p in {w where w is Element of (the carrier of U1)*: len w = arity o1}
	by A6,A22,A21;
	then p in (arity o1)-tuples_on the carrier of U1 by FINSEQ_2:def 4;
	then
	A25: p in dom o1 by MARGREL1:22;
	then
	A26: h1.(o2.x) = h1.(h.(o1.p)) by A4,A6,A7,A9,A11,A12,A20;
	A27: o1.p in the carrier of U1 by A25,PARTFUN1:4;
	then o1.p in dom h by FUNCT_2:def 1;
	hence h1.(o2.x) = (id the carrier of U1).(o1.p) by A23,A26,FUNCT_1:13
	.= o1.(h1*x) by A24,A27,FUNCT_1:17;
	end;
	hence thesis by A5;
	end;

	theorem Th10:
	for h be Function of U1,U2, h1 be Function of U2,U1 st h
	is_isomorphism & h1 = h" holds h1 is_isomorphism
	proof
	let h be Function of U1,U2,h1 be Function of U2,U1;
	assume that
	A1: h is_isomorphism and
	A2: h1=h";
	A3: h1 is_homomorphism by A1,A2,Th9;
	A4: h is one-to-one by A1,Th7;
	then rng h1 = dom h by A2,FUNCT_1:33
	.= the carrier of U1 by FUNCT_2:def 1;
	hence thesis by A2,A4,A3,Th7;
	end;

	theorem Th11:
	for h be Function of U1,U2, h1 be Function of U2,U3 st h
	is_isomorphism & h1 is_isomorphism holds h1 * h is_isomorphism
	proof
	let h be Function of U1,U2, h1 be Function of U2,U3;
	assume that
	A1: h is_isomorphism and
	A2: h1 is_isomorphism;
	dom h1 = the carrier of U2 & rng h = the carrier of U2 by A1,Th8,
	FUNCT_2:def 1;
	then
	A3: rng (h1 * h) = rng h1 by RELAT_1:28
	.= the carrier of U3 by A2,Th8;
	h is_homomorphism & h1 is_homomorphism by A1,A2,Th7;
	then
	A4: h1 * h is_homomorphism by Th6;
	h is one-to-one & h1 is one-to-one by A1,A2,Th7;
	hence thesis by A3,A4,Th7;
	end;

	theorem
	U1,U1 are_isomorphic
	proof
	set i = id the carrier of U1;
	i is_homomorphism & rng i = the carrier of U1 by Th5;
	then i is_isomorphism by Th7;
	hence thesis;
	end;

	theorem
	U1,U2 are_isomorphic implies U2,U1 are_isomorphic
	proof
	assume U1,U2 are_isomorphic;
	then consider f such that
	A1: f is_isomorphism;
	f is_monomorphism by A1;
	then
	A2: f is one-to-one;
	then
	A3: rng(f") = dom f by FUNCT_1:33
	.= the carrier of U1 by FUNCT_2:def 1;
	A4: f is_epimorphism by A1;
	dom(f") = rng f by A2,FUNCT_1:33
	.= the carrier of U2 by A4;
	then reconsider g = f" as Function of U2,U1 by A3,FUNCT_2:def 1,RELSET_1:4;
	take g;
	thus thesis by A1,Th10;
	end;

	theorem
	U1,U2 are_isomorphic & U2,U3 are_isomorphic implies U1,U3 are_isomorphic
	proof
	assume U1,U2 are_isomorphic;
	then consider f such that
	A1: f is_isomorphism;
	assume U2,U3 are_isomorphic;
	then consider g be Function of U2,U3 such that
	A2: g is_isomorphism;
	g * f is_isomorphism by A1,A2,Th11;
	hence thesis;
	end;

	definition
	let U1,U2,f;
	assume
	A1: f is_homomorphism;
	func Image f -> strict SubAlgebra of U2 means
	:Def6:
	the carrier of it = f .: (the carrier of U1);
	existence
	proof
	A2: dom f = the carrier of U1 by FUNCT_2:def 1;
	then reconsider A = f .: (the carrier of U1) as non empty Subset of U2;
	take B = UniAlgSetClosed(A);
	A is opers_closed
	proof
	let o2 be operation of U2;
	consider n being Nat such that
	A3: n in dom the charact of(U2) and
	A4: (the charact of U2).n = o2 by FINSEQ_2:10;
	let s be FinSequence of A;
	assume
	A5: len s = arity o2;
	defpred P[object,object] means f.$2 = s.$1;
	A6: for x being object st x in dom s
	ex y being object st y in the carrier of U1 & P[x,y]
	proof
	let x be object;
	assume
	A7: x in dom s;
	then reconsider x0 = x as Element of NAT;
	s.x0 in A by A7,FINSEQ_2:11;
	then consider y being object such that
	A8: y in dom f and
	y in the carrier of U1 and
	A9: f.y = s.x0 by FUNCT_1:def 6;
	take y;
	thus thesis by A8,A9;
	end;
	consider s1 be Function such that
	A10: dom s1 = dom s & rng s1 c= the carrier of U1 &
	for x being object st x in
	dom s holds P[x,s1.x] from FUNCT_1:sch 6(A6);
	dom s1 = Seg len s by A10,FINSEQ_1:def 3;
	then reconsider s1 as FinSequence by FINSEQ_1:def 2;
	reconsider s1 as FinSequence of U1 by A10,FINSEQ_1:def 4;
	reconsider s1 as Element of (the carrier of U1)* by FINSEQ_1:def 11;
	A11: len s1 = len s by A10,FINSEQ_3:29;
	A12: dom (signature U2) = Seg len (signature U2) by FINSEQ_1:def 3;
	A13: U1,U2 are_similar by A1;
	then
	A14: signature U1 = signature U2;
	A15: dom (signature U1) = dom (signature U2) by A13;
	A16: len (signature U2) = len the charact of(U2) & dom the charact of(U2)
	= Seg len the charact of(U2) by FINSEQ_1:def 3,UNIALG_1:def 4;
	then
	A17: (signature U2).n = arity o2 by A3,A4,A12,UNIALG_1:def 4;
	A18: len (f*s1) = len s1 by FINSEQ_3:120;
	A19: dom (fs1) = Seg len (fs1) & dom s = Seg len s1 by A10,FINSEQ_1:def 3;
	now
	let m be Nat;
	assume
	A20: m in dom s;
	then f.(s1.m) = s.m by A10;
	hence (f*s1).m = s.m by A18,A19,A20,FINSEQ_3:120;
	end;
	then
	A21: s = f*s1 by A11,A18,FINSEQ_2:9;
	A22: dom (signature U1) = Seg len (signature U1) by FINSEQ_1:def 3;
	A23: len (signature U1) = len the charact of(U1) & dom the charact of(U1)
	= Seg len the charact of(U1) by FINSEQ_1:def 3,UNIALG_1:def 4;
	then reconsider o1 = (the charact of U1).n as operation of U1 by A3,A16
	,A22,A15,A12,FUNCT_1:def 3;
	(signature U1).n = arity o1 by A3,A16,A15,A12,UNIALG_1:def 4;
	then
	s1 in {w where w is Element of (the carrier of U1)* : len w = arity
	o1 } by A14,A5,A17,A11;
	then s1 in (arity o1)-tuples_on the carrier of U1 by FINSEQ_2:def 4;
	then
	A24: s1 in dom o1 by MARGREL1:22;
	then
	A25: o1.s1 in rng o1 by FUNCT_1:def 3;
	f.(o1.s1) = o2.(f*s1) by A1,A3,A4,A23,A16,A22,A15,A12,A24;
	hence thesis by A2,A21,A25,FUNCT_1:def 6;
	end;
	then B = UAStr (# A,Opers(U2,A) #) by UNIALG_2:def 8;
	hence thesis;
	end;
	uniqueness
	proof
	let A,B be strict SubAlgebra of U2;
	reconsider A1 = the carrier of A as non empty Subset of U2
	by UNIALG_2:def 7;
	the charact of(A) = Opers(U2,A1) by UNIALG_2:def 7;
	hence thesis by UNIALG_2:def 7;
	end;
	end;

	theorem
	for h be Function of U1,U2 st h is_homomorphism holds rng h =
	the carrier of Image h
	proof
	let h be Function of U1,U2;
	dom h = the carrier of U1 by FUNCT_2:def 1;
	then
	A1: rng h = h.:(the carrier of U1) by RELAT_1:113;
	assume h is_homomorphism;
	hence thesis by A1,Def6;
	end;

	theorem
	for U2 being strict Universal_Algebra, f be Function of U1,U2 st f
	is_homomorphism holds f is_epimorphism iff Image f = U2
	proof
	let U2 be strict Universal_Algebra;
	let f be Function of U1,U2;
	assume
	A1: f is_homomorphism;
	thus f is_epimorphism implies Image f = U2
	proof
	reconsider B = the carrier of Image f as non empty Subset of U2 by
	UNIALG_2:def 7;
	assume f is_epimorphism;
	then
	A2: the carrier of U2 = rng f
	.= f.:(dom f) by RELAT_1:113
	.= f.:(the carrier of U1) by FUNCT_2:def 1
	.= the carrier of Image f by A1,Def6;
	the charact of(Image f) = Opers(U2,B) by UNIALG_2:def 7;
	hence thesis by A2,Th1;
	end;
	assume Image f = U2;
	then the carrier of U2 = f.:(the carrier of U1) by A1,Def6
	.= f.:(dom f) by FUNCT_2:def 1
	.= rng f by RELAT_1:113;
	hence thesis by A1;
	end;

	begin :: Quotient Universal Algebra

	definition
	let U1 be 1-sorted;
	mode Relation of U1 is Relation of the carrier of U1;
	mode Equivalence_Relation of U1 is Equivalence_Relation of the carrier of U1;
	end;

	definition
	let U1;
	mode Congruence of U1 -> Equivalence_Relation of U1 means
	:Def7:
	for n,o1
	st n in dom the charact of(U1) & o1 = (the charact of U1).n for x,y be
	FinSequence of U1 st x in dom o1 & y in dom o1 & [x,y] in ExtendRel(it) holds [
	o1.x,o1.y] in it;
	existence
	proof
	reconsider P = id the carrier of U1 as Equivalence_Relation of U1;
	take P;
	let n,o1;
	assume that
	n in dom the charact of(U1) and
	o1 = (the charact of U1).n;
	let x,y be FinSequence of U1;
	assume that
	A1: x in dom o1 and
	y in dom o1 and
	A2: [x,y] in ExtendRel(P);
	[x,y] in id ((the carrier of U1)*) by A2,FINSEQ_3:121;
	then
	A3: x = y by RELAT_1:def 10;
	o1.x in rng o1 by A1,FUNCT_1:def 3;
	hence thesis by A3,RELAT_1:def 10;
	end;
	end;

	reserve E for Congruence of U1;

	definition
	let U1 be Universal_Algebra, E be Congruence of U1, o be operation of U1;
	func QuotOp(o,E) -> homogeneous quasi_total non empty PartFunc of (Class E)*
	,(Class E) means
	:Def8:
	dom it = (arity o)-tuples_on (Class E) & for y be
	FinSequence of (Class E) st y in dom it for x be FinSequence of the carrier of
	U1 st x is_representatives_FS y holds it.y = Class(E,o.x);
	existence
	proof
	defpred P[object,object] means
	for y be FinSequence of (Class E) st y = $1 holds
	for x be FinSequence of the carrier of U1 st x is_representatives_FS y holds $2
	= Class(E,o.x);
	set X = (arity o)-tuples_on (Class E);
	A1: for e be object st e in X ex u be object st u in Class(E) & P[e,u]
	proof
	let e be object;
	A2: dom o = (arity o)-tuples_on the carrier of U1 by MARGREL1:22
	.={q where q is Element of (the carrier of U1)*: len q = arity o} by
	FINSEQ_2:def 4;
	assume e in X;
	then e in {s where s is Element of (Class E)*: len s = arity o} by
	FINSEQ_2:def 4;
	then consider s be Element of (Class E)* such that
	A3: s = e and
	A4: len s = arity o;
	consider x be FinSequence of the carrier of U1 such that
	A5: x is_representatives_FS s by FINSEQ_3:122;
	take y = Class(E,o.x);
	A6: len x = arity o by A4,A5,FINSEQ_3:def 4;
	x is Element of (the carrier of U1)* by FINSEQ_1:def 11;
	then
	A7: x in dom o by A2,A6;
	then
	A8: o.x in rng o by FUNCT_1:def 3;
	hence y in Class E by EQREL_1:def 3;
	let a be FinSequence of (Class E);
	assume
	A9: a = e;
	let b be FinSequence of the carrier of U1;
	assume
	A10: b is_representatives_FS a;
	then
	A11: len b = arity o by A3,A4,A9,FINSEQ_3:def 4;
	for m st m in dom x holds [x.m,b.m] in E
	proof
	let m;
	assume
	A12: m in dom x;
	then
	A13: Class(E,x.m) = s.m & x.m in rng x by A5,FINSEQ_3:def 4,FUNCT_1:def 3;
	dom x = Seg arity o by A6,FINSEQ_1:def 3
	.= dom b by A11,FINSEQ_1:def 3;
	then Class(E,b.m) = s.m by A3,A9,A10,A12,FINSEQ_3:def 4;
	hence thesis by A13,EQREL_1:35;
	end;
	then
	A14: [x,b] in ExtendRel(E) by A6,A11,FINSEQ_3:def 3;
	b is Element of (the carrier of U1)* by FINSEQ_1:def 11;
	then
	(ex n being Nat st n in dom the charact of(U1) & (the charact of U1
	).n = o ) & b in dom o by A2,A11,FINSEQ_2:10;
	then [o.x,o.b] in E by A7,A14,Def7;
	hence thesis by A8,EQREL_1:35;
	end;
	consider F being Function such that
	A15: dom F = X & rng F c= Class(E) & for e be object st e in X holds P[e,
	F.e] from FUNCT_1:sch 6(A1);
	X in the set of all m-tuples_on Class E;
	then X c= union the set of all m-tuples_on Class E by ZFMISC_1:74;
	then X c= (Class E)* by FINSEQ_2:108;
	then reconsider F as PartFunc of (Class E)*,Class E by A15,RELSET_1:4;
	A16: dom F = {t where t is Element of (Class E)*: len t = arity o} by A15,
	FINSEQ_2:def 4;
	A17: for x,y be FinSequence of Class E st len x = len y & x in dom F holds
	y in dom F
	proof
	let x,y be FinSequence of Class E;
	assume that
	A18: len x = len y and
	A19: x in dom F;
	A20: y is Element of (Class E)* by FINSEQ_1:def 11;
	ex t1 be Element of (Class E)* st x = t1 & len t1 = arity o by A16,A19;
	hence thesis by A16,A18,A20;
	end;
	A21: ex x being FinSequence st x in dom F
	proof
	set a = the Element of X;
	a in X;
	hence ex x being FinSequence st x in dom F by A15;
	end;
	dom F is with_common_domain
	proof
	let x,y be FinSequence;
	assume x in dom F & y in dom F;
	then (ex t1 be Element of (Class E)* st x = t1 & len t1 = arity o )& ex
	t2 be Element of (Class E)* st y = t2 & len t2 = arity o by A16;
	hence thesis;
	end;
	then reconsider
	F as homogeneous quasi_total non empty PartFunc of (Class E)*,
	Class E by A17,A21,MARGREL1:def 21,def 22;
	take F;
	thus dom F = (arity o)-tuples_on (Class E) by A15;
	let y be FinSequence of (Class E);
	assume
	A22: y in dom F;
	let x be FinSequence of the carrier of U1;
	assume x is_representatives_FS y;
	hence thesis by A15,A22;
	end;
	uniqueness
	proof
	let F,G be homogeneous quasi_total non empty PartFunc of (Class(E))*,Class
	(E);
	assume that
	A23: dom F = (arity o)-tuples_on (Class E) and
	A24: for y be FinSequence of Class(E) st y in dom F for x be
	FinSequence of the carrier of U1 st x is_representatives_FS y holds F.y = Class
	(E,o.x) and
	A25: dom G = (arity(o))-tuples_on (Class(E)) and
	A26: for y be FinSequence of Class(E) st y in dom G for x be
	FinSequence of the carrier of U1 st x is_representatives_FS y holds G.y = Class
	(E,o.x);
	for a be object st a in dom F holds F.a = G.a
	proof
	let a be object;
	assume
	A27: a in dom F;
	then reconsider b = a as FinSequence of Class(E) by FINSEQ_1:def 11;
	consider x be FinSequence of the carrier of U1 such that
	A28: x is_representatives_FS b by FINSEQ_3:122;
	F.b = Class(E,o.x) by A24,A27,A28;
	hence thesis by A23,A25,A26,A27,A28;
	end;
	hence thesis by A23,A25;
	end;
	end;

	definition
	let U1,E;
	func QuotOpSeq(U1,E) -> PFuncFinSequence of Class E means
	:Def9:
	len it =
	len the charact of(U1) & for n st n in dom it for o1 st (the charact of(U1)).n
	= o1 holds it.n = QuotOp(o1,E);
	existence
	proof
	defpred P[set,set] means for o be Element of Operations(U1) st o = (the
	charact of(U1)).$1 holds $2 = QuotOp(o,E);
	A1: for n be Nat st n in Seg len the charact of(U1) ex x be Element of
	PFuncs((Class E)*,(Class E)) st P[n,x]
	proof
	let n be Nat;
	assume n in Seg len the charact of(U1);
	then n in dom the charact of(U1) by FINSEQ_1:def 3;
	then reconsider o = (the charact of(U1)).n as operation of U1 by
	FUNCT_1:def 3;
	reconsider x = QuotOp(o,E) as Element of PFuncs((Class E)*,(Class E)) by
	PARTFUN1:45;
	take x;
	thus thesis;
	end;
	consider p be FinSequence of PFuncs((Class E)*,(Class E)) such that
	A2: dom p = Seg len the charact of(U1) & for n be Nat st n in Seg len
	the charact of(U1) holds P[n,p.n] from FINSEQ_1:sch 5(A1);
	reconsider p as PFuncFinSequence of Class E;
	take p;
	thus len p = len the charact of(U1) by A2,FINSEQ_1:def 3;
	let n;
	assume n in dom p;
	hence thesis by A2;
	end;
	uniqueness
	proof
	let F,G be PFuncFinSequence of Class E;
	assume that
	A3: len F = len the charact of(U1) and
	A4: for n st n in dom F for o1 st (the charact of(U1)).n = o1 holds F.
	n = QuotOp(o1,E) and
	A5: len G = len the charact of(U1) and
	A6: for n st n in dom G for o1 st (the charact of(U1)).n = o1 holds G.
	n = QuotOp(o1,E);
	now
	let n be Nat;
	assume
	A7: n in dom F;
	dom F = Seg len the charact of(U1) by A3,FINSEQ_1:def 3;
	then n in dom the charact of(U1) by A7,FINSEQ_1:def 3;
	then reconsider o1 = (the charact of U1).n as operation of U1 by
	FUNCT_1:def 3;
	A8: dom F = dom the charact of(U1) & dom G = dom the charact of(U1) by A3,A5,
	FINSEQ_3:29;
	F.n = QuotOp(o1,E) by A4,A7;
	hence F.n = G.n by A6,A8,A7;
	end;
	hence thesis by A3,A5,FINSEQ_2:9;
	end;
	end;

	definition
	let U1,E;
	func QuotUnivAlg(U1,E) -> strict Universal_Algebra equals
	UAStr (# Class(E),QuotOpSeq(U1,E) #);
	coherence
	proof
	set UU = UAStr (# Class(E),QuotOpSeq(U1,E) #);
	for n be Nat,h be PartFunc of (Class E)*,(Class E) st n in dom QuotOpSeq
	(U1,E) & h = QuotOpSeq(U1,E).n holds h is homogeneous
	proof
	let n be Nat,h be PartFunc of (Class E)*,(Class E);
	assume that
	A1: n in dom QuotOpSeq(U1,E) and
	A2: h = QuotOpSeq(U1,E).n;
	n in Seg len QuotOpSeq(U1,E) by A1,FINSEQ_1:def 3;
	then n in Seg len the charact of U1 by Def9;
	then n in dom the charact of U1 by FINSEQ_1:def 3;
	then reconsider o = (the charact of U1).n as operation of U1 by
	FUNCT_1:def 3;
	QuotOpSeq(U1,E).n = QuotOp(o,E) by A1,Def9;
	hence thesis by A2;
	end;
	then
	A3: the charact of UU is homogeneous;
	for n be Nat ,h be PartFunc of (Class E)*,(Class E) st n in dom
	QuotOpSeq(U1,E) & h = QuotOpSeq(U1,E).n holds h is quasi_total
	proof
	let n be Nat,h be PartFunc of (Class E)*,(Class E);
	assume that
	A4: n in dom QuotOpSeq(U1,E) and
	A5: h = QuotOpSeq(U1,E).n;
	n in Seg len QuotOpSeq(U1,E) by A4,FINSEQ_1:def 3;
	then n in Seg len the charact of(U1) by Def9;
	then n in dom the charact of U1 by FINSEQ_1:def 3;
	then reconsider o = (the charact of U1).n as operation of U1 by
	FUNCT_1:def 3;
	QuotOpSeq(U1,E).n = QuotOp(o,E) by A4,Def9;
	hence thesis by A5;
	end;
	then
	A6: the charact of UU is quasi_total;
	for n be object st n in dom QuotOpSeq(U1,E)
	holds QuotOpSeq(U1,E).n is non empty
	proof
	let n be object;
	assume
	A7: n in dom QuotOpSeq(U1,E);
	then n in Seg len QuotOpSeq(U1,E) by FINSEQ_1:def 3;
	then n in Seg len the charact of U1 by Def9;
	then
	A8: n in dom the charact of U1 by FINSEQ_1:def 3;
	reconsider n as Element of NAT by A7;
	reconsider o = (the charact of U1).n as operation of U1
	by A8,FUNCT_1:def 3;
	QuotOpSeq(U1,E).n = QuotOp(o,E) by A7,Def9;
	hence thesis;
	end;
	then
	A9: the charact of UU is non-empty by FUNCT_1:def 9;
	the charact of UU <> {}
	proof
	assume
	A10: the charact of UU = {};
	len the charact of UU = len the charact of U1 by Def9;
	hence contradiction by A10;
	end;
	hence thesis by A3,A6,A9,UNIALG_1:def 1,def 2,def 3;
	end;
	end;

	definition
	let U1,E;
	func Nat_Hom(U1,E) -> Function of U1,QuotUnivAlg(U1,E) means
	:Def11:
	for u be Element of U1 holds it.u = Class(E,u);
	existence
	proof
	defpred P[Element of U1,set] means $2 = Class(E,$1);
	A1: for x being Element of U1 ex y being Element of QuotUnivAlg(U1,E) st P
	[x,y]
	proof
	let x be Element of U1;
	reconsider y = Class(E,x) as Element of QuotUnivAlg(U1,E) by
	EQREL_1:def 3;
	take y;
	thus thesis;
	end;
	consider f being Function of U1,QuotUnivAlg(U1,E) such that
	A2: for x being Element of U1 holds P[x,f.x] from FUNCT_2:sch 3(A1);
	take f;
	thus thesis by A2;
	end;
	uniqueness
	proof
	let f,g be Function of U1,QuotUnivAlg(U1,E);
	assume that
	A3: for u be Element of U1 holds f.u = Class(E,u) and
	A4: for u be Element of U1 holds g.u = Class(E,u);
	now
	let u be Element of U1;
	f.u = Class(E,u) by A3;
	hence f.u = g.u by A4;
	end;
	hence thesis;
	end;
	end;

	theorem Th17:
	for U1,E holds Nat_Hom(U1,E) is_homomorphism
	proof
	let U1,E;
	set f = Nat_Hom(U1,E), u1 = the carrier of U1, qu = the carrier of
	QuotUnivAlg(U1,E);
	A1: len (signature U1) = len the charact of(U1) by UNIALG_1:def 4;
	A2: dom (signature U1) = Seg len(signature U1) by FINSEQ_1:def 3;
	A3: len QuotOpSeq(U1,E) = len the charact of(U1) by Def9;
	A4: len (signature QuotUnivAlg(U1,E)) = len the charact of(QuotUnivAlg(U1,E)
	) by UNIALG_1:def 4;
	now
	let n be Nat;
	assume
	A5: n in dom (signature U1);
	then n in dom the charact of(U1) by A1,A2,FINSEQ_1:def 3;
	then reconsider o1 = (the charact of U1).n as operation of U1 by
	FUNCT_1:def 3;
	n in dom QuotOpSeq(U1,E) by A3,A1,A2,A5,FINSEQ_1:def 3;
	then
	A6: QuotOpSeq(U1,E).n = QuotOp(o1,E) by Def9;
	reconsider cl = QuotOp(o1,E) as homogeneous quasi_total non empty PartFunc
	of qu*,qu;
	consider b be object such that
	A7: b in dom cl by XBOOLE_0:def 1;
	reconsider b as Element of qu* by A7;
	dom QuotOp(o1,E) = (arity o1)-tuples_on Class(E) by Def8;
	then b in {w where w is Element of (Class(E))*: len w = arity o1} by A7,
	FINSEQ_2:def 4;
	then ex w be Element of (Class(E))* st w = b & len w = arity o1;
	then
	A8: arity cl = arity o1 by A7,MARGREL1:def 25;
	n in dom (signature QuotUnivAlg(U1,E)) & (signature U1).n = arity o1
	by A3,A4,A2,A5,FINSEQ_1:def 3,UNIALG_1:def 4;
	hence (signature U1).n = (signature QuotUnivAlg(U1,E)).n by A6,A8,
	UNIALG_1:def 4;
	end;
	hence signature U1 = signature QuotUnivAlg(U1,E) by A3,A4,A1,FINSEQ_2:9;
	let n;
	assume n in dom the charact of(U1);
	then n in Seg len the charact of(U1) by FINSEQ_1:def 3;
	then
	A9: n in dom QuotOpSeq(U1,E) by A3,FINSEQ_1:def 3;
	let o1 be operation of U1, o2 be operation of QuotUnivAlg(U1,E);
	assume
	(the charact of U1).n = o1 & o2 = (the charact of QuotUnivAlg(U1,E) ).n;
	then
	A10: o2 = QuotOp(o1,E) by A9,Def9;
	let x be FinSequence of U1;
	reconsider x1 = x as Element of u1* by FINSEQ_1:def 11;
	reconsider fx = f*x as FinSequence of Class(E);
	reconsider fx as Element of (Class(E))* by FINSEQ_1:def 11;
	A11: len (f*x) = len x by FINSEQ_3:120;
	now
	let m;
	assume
	A12: m in dom x;
	then
	A13: m in dom(f*x) by FINSEQ_3:120;
	x.m in rng x by A12,FUNCT_1:def 3;
	then reconsider xm = x.m as Element of u1;
	thus Class(E,x.m) = f.xm by Def11
	.= fx.m by A13,FINSEQ_3:120;
	end;
	then
	A14: x is_representatives_FS fx by A11,FINSEQ_3:def 4;
	assume
	A15: x in dom o1;
	then o1.x in rng o1 by FUNCT_1:def 3;
	then reconsider ox = o1.x as Element of u1;
	dom o1 = (arity o1)-tuples_on u1 by MARGREL1:22
	.= {p where p is Element of u1* : len p = arity o1} by FINSEQ_2:def 4;
	then
	A16: ex p be Element of u1* st p = x1 & len p = arity o1 by A15;
	A17: f.(o1.x) = Class(E,ox) by Def11
	.= Class(E,o1.x);
	dom QuotOp(o1,E) = (arity o1)-tuples_on Class(E) by Def8
	.= {q where q is Element of (Class(E))*: len q = arity o1} by
	FINSEQ_2:def 4;
	then fx in dom QuotOp(o1,E) by A16,A11;
	hence thesis by A17,A10,A14,Def8;
	end;

	theorem
	for U1,E holds Nat_Hom(U1,E) is_epimorphism
	proof
	let U1,E;
	set f = Nat_Hom(U1,E), qa = QuotUnivAlg(U1,E), cqa = the carrier of qa, u1 =
	the carrier of U1;
	thus f is_homomorphism by Th17;
	thus rng f c= cqa;
	let x be object;
	assume
	A1: x in cqa;
	then reconsider x1 = x as Subset of u1;
	consider y being object such that
	A2: y in u1 and
	A3: x1 = Class(E,y) by A1,EQREL_1:def 3;
	reconsider y as Element of u1 by A2;
	dom f = u1 by FUNCT_2:def 1;
	then f.y in rng f by FUNCT_1:def 3;
	hence thesis by A3,Def11;
	end;

	definition
	let U1,U2;
	let f be Function of U1,U2;
	assume
	A1: f is_homomorphism;
	func Cng(f) -> Congruence of U1 means
	:Def12:
	for a,b be Element of U1 holds [a,b] in it iff f.a = f.b;
	existence
	proof
	defpred P[set,set] means f.$1 = f.$2;
	set u1 = the carrier of U1;
	consider R being Relation of u1,u1 such that
	A2: for x,y being Element of u1 holds [x,y] in R iff P[x,y] from
	RELSET_1:sch 2;
	R is_reflexive_in u1
	proof
	let x be object;
	assume x in u1;
	then reconsider x1 = x as Element of u1;
	f.x1 =f.x1;
	hence thesis by A2;
	end;
	then
	A3: dom R = u1 & field R = u1 by ORDERS_1:13;
	A4: R is_transitive_in u1
	proof
	let x,y,z be object;
	assume that
	A5: x in u1 & y in u1 & z in u1 and
	A6: [x,y] in R & [y,z] in R;
	reconsider x1 = x, y1=y, z1 = z as Element of u1 by A5;
	f.x1 = f.y1 & f.y1 = f.z1 by A2,A6;
	hence thesis by A2;
	end;
	R is_symmetric_in u1
	proof
	let x,y be object;
	assume that
	A7: x in u1 & y in u1 and
	A8: [x,y] in R;
	reconsider x1 = x, y1=y as Element of u1 by A7;
	f.x1 = f.y1 by A2,A8;
	hence thesis by A2;
	end;
	then reconsider R as Equivalence_Relation of U1 by A3,A4,PARTFUN1:def 2
	,RELAT_2:def 11,def 16;
	now
	U1,U2 are_similar by A1;
	then
	A9: signature U1 = signature U2;
	let n be Nat,o be operation of U1;
	assume that
	A10: n in dom the charact of(U1) and
	A11: o = (the charact of U1).n;
	len (signature U1) = len the charact of(U1) & len (signature U2) =
	len the charact of(U2) by UNIALG_1:def 4;
	then dom the charact of(U2) = dom the charact of(U1) by A9,FINSEQ_3:29;
	then reconsider o2 = (the charact of U2).n as operation of U2 by A10,
	FUNCT_1:def 3;
	let x,y be FinSequence of U1;
	assume that
	A12: x in dom o & y in dom o and
	A13: [x,y] in ExtendRel(R);
	o.x in rng o & o.y in rng o by A12,FUNCT_1:def 3;
	then reconsider ox = o.x, oy = o.y as Element of u1;
	A14: len x = len y by A13,FINSEQ_3:def 3;
	A15: len (f*y) = len y by FINSEQ_3:120;
	then
	A16: dom (f*y) = Seg len x by A14,FINSEQ_1:def 3;
	A17: len (f*x) = len x by FINSEQ_3:120;
	A18: now
	let m be Nat;
	assume
	A19: m in dom (f*y);
	then m in dom y by A14,A16,FINSEQ_1:def 3;
	then
	A20: y.m in rng y by FUNCT_1:def 3;
	A21: m in dom x by A16,A19,FINSEQ_1:def 3;
	then x.m in rng x by FUNCT_1:def 3;
	then reconsider xm = x.m, ym = y.m as Element of u1 by A20;
	[x.m,y.m] in R by A13,A21,FINSEQ_3:def 3;
	then
	A22: f.xm = f.ym by A2
	.= (f*y).m by A19,FINSEQ_3:120;
	m in dom (f*x) by A17,A16,A19,FINSEQ_1:def 3;
	hence (fy).m = (fx).m by A22,FINSEQ_3:120;
	end;
	f.(o.x) = o2.(fx) & f.(o.y) = o2.(fy) by A1,A10,A11,A12;
	then f.(ox) = f.(oy) by A14,A17,A15,A18,FINSEQ_2:9;
	hence [o.x,o.y] in R by A2;
	end;
	then reconsider R as Congruence of U1 by Def7;
	take R;
	let a,b be Element of u1;
	thus [a,b] in R implies f.a = f.b by A2;
	assume f.a = f.b;
	hence thesis by A2;
	end;
	uniqueness
	proof
	set u1 = the carrier of U1;
	let X,Y be Congruence of U1;
	assume that
	A23: for a,b be Element of U1 holds [a,b] in X iff f.a = f.b and
	A24: for a,b be Element of U1 holds [a,b] in Y iff f.a = f.b;
	for x,y be object holds [x,y] in X iff [x,y] in Y
	proof
	let x,y be object;
	thus [x,y] in X implies [x,y] in Y
	proof
	assume
	A25: [x,y] in X;
	then reconsider x1 = x,y1 = y as Element of u1 by ZFMISC_1:87;
	f.x1 = f.y1 by A23,A25;
	hence thesis by A24;
	end;
	assume
	A26: [x,y] in Y;
	then reconsider x1 = x,y1 = y as Element of u1 by ZFMISC_1:87;
	f.x1 = f.y1 by A24,A26;
	hence thesis by A23;
	end;
	hence thesis by RELAT_1:def 2;
	end;
	end;

	definition
	let U1,U2 be Universal_Algebra, f be Function of U1,U2;
	assume
	A1: f is_homomorphism;
	func HomQuot(f) -> Function of QuotUnivAlg(U1,Cng(f)),U2 means
	:Def13:
	for a be Element of U1 holds it.(Class(Cng f,a)) = f.a;
	existence
	proof
	set qa = QuotUnivAlg(U1,Cng(f)), cqa = the carrier of qa, u1 = the carrier
	of U1, u2 = the carrier of U2;
	defpred P[object,object] means
	for a be Element of u1 st $1 = Class(Cng f,a)
	holds $2 = f.a;
	A2: for x being object st x in cqa ex y being object st y in u2 & P[x,y]
	proof
	let x be object;
	assume
	A3: x in cqa;
	then reconsider x1 = x as Subset of u1;
	consider a be object such that
	A4: a in u1 and
	A5: x1 = Class(Cng f,a) by A3,EQREL_1:def 3;
	reconsider a as Element of u1 by A4;
	take y = f.a;
	thus y in u2;
	let b be Element of u1;
	assume x = Class(Cng f,b);
	then b in Class(Cng f,a) by A5,EQREL_1:23;
	then [b,a] in Cng(f) by EQREL_1:19;
	hence thesis by A1,Def12;
	end;
	consider F being Function such that
	A6: dom F = cqa & rng F c= u2 & for x being object st x in cqa holds P[x,F.x]
	from
	FUNCT_1:sch 6(A2);
	reconsider F as Function of qa,U2 by A6,FUNCT_2:def 1,RELSET_1:4;
	take F;
	let a be Element of u1;
	Class(Cng f,a) in Class(Cng f) by EQREL_1:def 3;
	hence thesis by A6;
	end;
	uniqueness
	proof
	set qa = QuotUnivAlg(U1,Cng(f)), cqa = the carrier of qa, u1 = the carrier
	of U1;
	let F,G be Function of qa,U2;
	assume that
	A7: for a be Element of u1 holds F.(Class(Cng f,a)) = f.a and
	A8: for a be Element of u1 holds G.(Class(Cng f,a)) = f.a;
	let x be Element of cqa;
	x in cqa;
	then reconsider x1 = x as Subset of u1;
	consider a be object such that
	A9: a in u1 & x1 = Class(Cng f,a) by EQREL_1:def 3;
	thus F.x = f.a by A7,A9
	.= G.x by A8,A9;
	end;
	end;

	theorem Th19:
	f is_homomorphism implies HomQuot(f) is_homomorphism
	& HomQuot(f) is_monomorphism
	proof
	set qa = QuotUnivAlg(U1,Cng(f)), cqa = the carrier of qa, u1 = the carrier
	of U1, F = HomQuot(f);
	assume
	A1: f is_homomorphism;
	thus
	A2: F is_homomorphism
	proof
	Nat_Hom(U1,Cng f) is_homomorphism by Th17;
	then U1,qa are_similar;
	then
	A3: signature U1 = signature qa;
	U1,U2 are_similar by A1;
	then signature U2 = signature qa by A3;
	hence qa,U2 are_similar;
	let n;
	assume
	A4: n in dom the charact of(qa);
	A5: len (signature U1) = len the charact of(U1) & len (signature qa) =
	len the charact of(qa) by UNIALG_1:def 4;
	A6: dom the charact of(qa) = Seg len (the charact of qa) & dom the
	charact of(U1 ) = Seg len (the charact of U1) by FINSEQ_1:def 3;
	then reconsider o1 = (the charact of U1).n as operation of U1 by A3,A4,A5,
	FUNCT_1:def 3;
	A7: dom o1 = (arity o1)-tuples_on u1 by MARGREL1:22
	.= {p where p is Element of u1* : len p = arity o1} by FINSEQ_2:def 4;
	let oq be operation of qa, o2 be operation of U2;
	assume that
	A8: oq = (the charact of qa).n and
	A9: o2 = (the charact of U2).n;
	let x be FinSequence of qa;
	assume
	A10: x in dom oq;
	reconsider x1 = x as FinSequence of Class(Cng f);
	reconsider x1 as Element of (Class(Cng f))* by FINSEQ_1:def 11;
	consider y be FinSequence of U1 such that
	A11: y is_representatives_FS x1 by FINSEQ_3:122;
	reconsider y as Element of u1* by FINSEQ_1:def 11;
	A12: len x1 = len y by A11,FINSEQ_3:def 4;
	then
	A13: len (F*x) = len y by FINSEQ_3:120;
	A14: len y = len (f*y) by FINSEQ_3:120;
	A15: now
	let m be Nat;
	assume
	A16: m in Seg len y;
	then
	A17: m in dom (F*x) by A13,FINSEQ_1:def 3;
	A18: m in dom(f*y) by A14,A16,FINSEQ_1:def 3;
	A19: m in dom y by A16,FINSEQ_1:def 3;
	then reconsider ym = y.m as Element of u1 by FINSEQ_2:11;
	x1.m = Class(Cng f,y.m) by A11,A19,FINSEQ_3:def 4;
	hence (F*x).m = F.(Class(Cng f,ym)) by A17,FINSEQ_3:120
	.= f.(y.m) by A1,Def13
	.= (f*y).m by A18,FINSEQ_3:120;
	end;
	dom(F*x) = Seg len y by A13,FINSEQ_1:def 3;
	then
	A20: o2.(Fx) = o2.(fy) by A13,A14,A15,FINSEQ_2:9;
	A21: oq = QuotOp(o1,Cng f) by A4,A8,Def9;
	then dom oq = (arity o1)-tuples_on Class(Cng f) by Def8
	.= {w where w is Element of (Class(Cng f))*: len w = arity o1} by
	FINSEQ_2:def 4;
	then ex w be Element of (Class(Cng f))* st w = x1 & len w = arity o1 by A10
	;
	then
	A22: y in dom o1 by A12,A7;
	then o1.y in rng o1 by FUNCT_1:def 3;
	then reconsider o1y = o1.y as Element of u1;
	F.(oq.x) = F.(Class(Cng f,o1y)) by A10,A11,A21,Def8
	.= f.(o1.y) by A1,Def13;
	hence thesis by A1,A3,A4,A9,A6,A5,A22,A20;
	end;
	A23: dom F = cqa by FUNCT_2:def 1;
	F is one-to-one
	proof
	let x,y be object;
	assume that
	A24: x in dom F and
	A25: y in dom F and
	A26: F.x = F.y;
	reconsider x1 = x, y1 = y as Subset of u1 by A23,A24,A25;
	consider a be object such that
	A27: a in u1 and
	A28: x1 = Class(Cng f,a) by A24,EQREL_1:def 3;
	reconsider a as Element of u1 by A27;
	consider b be object such that
	A29: b in u1 and
	A30: y1 = Class(Cng f,b) by A25,EQREL_1:def 3;
	reconsider b as Element of u1 by A29;
	A31: F.y1 = f.b by A1,A30,Def13;
	F.x1 = f.a by A1,A28,Def13;
	then [a,b] in Cng(f) by A1,A26,A31,Def12;
	hence thesis by A28,A30,EQREL_1:35;
	end;
	hence thesis by A2;
	end;

	::$N First isomorphism theorem for universal algebras
	theorem Th20:
	f is_epimorphism implies HomQuot(f) is_isomorphism
	proof
	set qa = QuotUnivAlg(U1,Cng(f)), u1 = the carrier of U1, u2 = the carrier of
	U2, F = HomQuot(f);
	assume
	A1: f is_epimorphism;
	then
	A2: f is_homomorphism;
	then F is_monomorphism by Th19;
	then
	A3: F is one-to-one;
	A4: rng f = u2 by A1;
	A5: rng F = u2
	proof
	thus rng F c= u2;
	let x be object;
	assume x in u2;
	then consider y being object such that
	A6: y in dom f and
	A7: f.y = x by A4,FUNCT_1:def 3;
	reconsider y as Element of u1 by A6;
	set u = Class(Cng f,y);
	A8: dom F = the carrier of qa & u in Class(Cng f) by EQREL_1:def 3
	,FUNCT_2:def 1;
	F.u = x by A2,A7,Def13;
	hence thesis by A8,FUNCT_1:def 3;
	end;
	F is_homomorphism by A2,Th19;
	hence thesis by A3,A5,Th7;
	end;

	theorem
	f is_epimorphism implies QuotUnivAlg(U1,Cng(f)),U2 are_isomorphic
	proof
	assume
	A1: f is_epimorphism;
	take HomQuot(f);
	thus thesis by A1,Th20;
	end;