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hoskinson-center
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proof-pile

	:: Algebraic Numbers
	:: by Yasushige Watase

	environ

	vocabularies NUMBERS, FINSEQ_1, SUBSET_1, FUNCT_1, ARYTM_3, TARSKI, NAT_1,
	XBOOLE_0, SUPINF_2, ZFMISC_1, GROUP_1, STRUCT_0, POLYNOM1, POLYNOM2,
	C0SP1, REALSET1, ARYTM_1, RELAT_1, CARD_1, XXREAL_0, VECTSP_1, ALGSTR_0,
	FUNCT_7, AFINSQ_1, CARD_3, MESFUNC1, POLYNOM3, FUNCSDOM, ORDINAL4, INT_2,
	GAUSSINT, BINOP_2, COMPLFLD, EC_PF_1, XCMPLX_0, FINSEQ_2, INT_3,
	ALGSEQ_1, POLYNOM4, PARTFUN1, IDEAL_1, CARD_FIL, VECTSP_2, POLYNOM5,
	HURWITZ, RATFUNC1, MSSUBFAM, QUOFIELD, BINOP_1, RING_1, RING_2, LATTICES,
	GCD_1, RLVECT_1, ALGNUM_1, RAT_1, INT_1, WAYBEL_8;
	notations TARSKI, XBOOLE_0, ZFMISC_1, SUBSET_1, XTUPLE_0, MCART_1, DOMAIN_1,
	ORDINAL1, RELAT_1, FUNCT_1, RELSET_1, PARTFUN1, FUNCT_2, NUMBERS, INT_1,
	FUNCOP_1, BINOP_1, FUNCT_4, FUNCT_7, SETWISEO, FINSEQ_1, FINSEQ_2,
	XCMPLX_0, XXREAL_0, CARD_1, XREAL_0, PBOOLE, VALUED_0, NAT_1, NAT_D,
	RAT_1, NEWTON, BINOP_2, MEMBERED, STRUCT_0, ALGSTR_0, C0SP1, NORMSP_1,
	VFUNCT_1, VECTSP_2, ALGSEQ_1, ALGSTR_1, RLVECT_1, GROUP_1, VECTSP_1,
	RINGCAT1, RING_3, GROUP_6, RING_2, POLYNOM1, UPROOTS, HURWITZ, RATFUNC1,
	BINOM, INT_3, GCD_1, RVSUM_1, COMPLFLD, POLYNOM3, POLYNOM4, POLYNOM5,
	FVSUM_1, PRE_POLY, REALSET1, COMPLEX1, EC_PF_1, GAUSSINT, IDEAL_1,
	RING_1, MSSUBFAM, QUOFIELD, RING_4;
	constructors TARSKI, XBOOLE_0, ZFMISC_1, SUBSET_1, FUNCT_1, RELSET_1, NUMBERS,
	ORDINAL1, FUNCT_2, FINSEQ_1, FINSEQOP, STRUCT_0, ALGSTR_0, C0SP1,
	VECTSP_1, NORMSP_1, VFUNCT_1, POLYNOM3, SETWISEO, BINOP_1, REAL_1,
	RFINSEQ, FINSOP_1, BINARITH, VECTSP_2, GRCAT_1, REALSET2, QUOFIELD,
	ALGSTR_1, POLYNOM4, POLYNOM5, NAT_D, FVSUM_1, ALGSEQ_1, FUNCT_7, BINOP_2,
	INT_1, RLVECT_1, GROUP_1, RINGCAT1, MOD_4, GROUP_6, RING_3, RING_2,
	GROUP_4, FINSEQ_4, MATRIX_1, POLYNOM1, UPROOTS, HURWITZ, POLYNOM2,
	RING_4, XXREAL_2, XTUPLE_0, PARTFUN1, RVSUM_1, XCMPLX_0, RAT_1, NEWTON,
	VALUED_0, MEMBERED, NAT_1, FINSEQ_2, RATFUNC1, BINOM, GCD_1, IDEAL_1,
	EC_PF_1, GAUSSINT, AFINSQ_2, FUNCT_4, REALSET1, MSSUBFAM;
	registrations ALGSTR_0, GAUSSINT, CARD_1, INT_3, FINSEQ_2, FUNCT_2, INT_1,
	MEMBERED, NAT_1, NUMBERS, ORDINAL1, POLYNOM3, POLYNOM5, REALSET1,
	RELAT_1, RING_2, STRUCT_0, VECTSP_1, XREAL_0, RATFUNC1, RAT_1, XXREAL_0,
	COMPLFLD, XCMPLX_0, VALUED_0, POLYNOM4, ALGSTR_1, RLVECT_1, RING_1,
	RING_4, XBOOLE_0, RINGCAT1, RELSET_1;
	requirements NUMERALS, BOOLE, SUBSET, ARITHM, REAL;
	definitions VECTSP_1, GROUP_1, GROUP_6, ALGSTR_0;
	equalities BINOP_1, ALGSTR_0, REALSET1, FINSEQ_1, FINSEQ_2, XCMPLX_0,
	POLYNOM3, POLYNOM5, RATFUNC1, HURWITZ, STRUCT_0, GAUSSINT, INT_3;
	expansions STRUCT_0, SUBSET_1, FINSEQ_1, TARSKI, ALGSEQ_1, FUNCT_2, IDEAL_1,
	FUNCT_1, RING_2, ALGSTR_0, UPROOTS;
	theorems TARSKI, ZFMISC_1, FUNCT_1, XREAL_0, VECTSP_1, NORMSP_1, FINSEQ_1,
	FINSEQ_2, FINSEQ_3, NAT_1, XREAL_1, ORDINAL1, C0SP1, CARD_1, RELAT_1,
	XXREAL_0, SUBSET_1, GROUP_1, MATRIX_3, FVSUM_1, FUNCOP_1, POLYNOM3,
	POLYNOM5, RLVECT_1, IDEAL_1, BINOP_2, RING_3, GAUSSINT, INT_1, ALGSEQ_1,
	POLYNOM4, POLYNOM2, PARTFUN1, RING_2, RING_1, VECTSP_2, RING_4, XCMPLX_0,
	FUNCT_2, COMPLFLD, ALGSTR_0, STRUCT_0, GCD_1, EC_PF_1, RAT_1;
	schemes NAT_1, FINSEQ_2, FUNCT_2;

	begin :: Preliminaries

	reserve i,j for Nat;
	reserve A,B for Ring;

	theorem Th1:
	for L1,L2,L3 be Ring st L1 is Subring of L2 & L2 is Subring of L3 holds
	L1 is Subring of L3
	proof
	let L1,L2,L3 be Ring;
	assume that
	A1: L1 is Subring of L2 and
	A2: L2 is Subring of L3;
	A3: the carrier of L1 c= the carrier of L2
	& the addF of L1 = (the addF of L2) \|\| the carrier of L1
	& the multF of L1 = (the multF of L2) \|\| the carrier of L1
	& 1.L1 = 1.L2& 0.L1 = 0.L2 by A1,C0SP1:def 3;
	A4: the carrier of L2 c= the carrier of L3
	& the addF of L2= (the addF of L3) \|\| the carrier of L2
	& the multF of L2= (the multF of L3) \|\| the carrier of L2
	& 1.L2= 1.L3 & 0.L2= 0.L3 by A2,C0SP1:def 3;
	set A1 = [:the carrier of L1, the carrier of L1:];
	set A2 = [:the carrier of L2, the carrier of L2:];
	set A3 = [:the carrier of L3, the carrier of L3:];
	A8: the carrier of L1 c= the carrier of L3 by A3,A4;
	A9: the addF of L1 = (the addF of L2) \|\| the carrier of L1
	by A1,C0SP1:def 3
	.= ((the addF of L3) \|\| the carrier of L2) \|\| the carrier of L1
	by A2,C0SP1:def 3
	.= (the addF of L3) \|\| the carrier of L1 by A3,ZFMISC_1:96,RELAT_1:74;
	A10: the multF of L1 = (the multF of L2) \|\| the carrier of L1
	by A1,C0SP1:def 3
	.= ((the multF of L3) \|\| the carrier of L2) \|\| the carrier of L1
	by A2,C0SP1:def 3
	.= (the multF of L3) \|\| the carrier of L1 by A3,ZFMISC_1:96,RELAT_1:74;
	A11: 1.L1 = 1.L2 by A1,C0SP1:def 3 .=1.L3 by A2,C0SP1:def 3;
	0.L1 = 0.L2 by A1,C0SP1:def 3 .=0.L3 by A2,C0SP1:def 3;
	hence thesis by A8,A9,A10,A11,C0SP1:def 3;
	end;

	theorem Lm1:
	F_Rat is Subfield of F_Complex by EC_PF_1:5,GAUSSINT:14,RING_3:48;

	theorem Th3:
	F_Rat is Subring of F_Complex by RING_3:43,Lm1;

	theorem Th4:
	INT.Ring is Subring of F_Complex by RING_3:47,Th3,Th1;

	Lm5:
	A is Subring of B implies In(0.A, B) = 0.B & In(1.A,B) = 1.B
	proof
	assume
	A1: A is Subring of B; then
	A2: In(0.A,B) = In(0.B,B) by C0SP1:def 3
	.= 0.B by SUBSET_1:def 8;
	In(1.A,B) = In(1.B,B) by A1,C0SP1:def 3
	.= 1.B by SUBSET_1:def 8;
	hence thesis by A2;
	end;

	Lm6:
	for a be Element of A st A is Subring of B holds a is Element of B
	proof
	let a be Element of A;
	assume A is Subring of B; then
	the carrier of A c= the carrier of B by C0SP1:def 3;
	hence thesis;
	end;

	Lm7:
	In(0.F_Rat,F_Complex) = 0.F_Complex &
	In(1.F_Rat,F_Complex) = 1.F_Complex &
	In(0.INT.Ring,F_Complex) = 0.F_Complex &
	In(1.INT.Ring,F_Complex) = 1.F_Complex by Lm5,Th3,Th4;

	theorem Th8:
	for x, y be Element of B, x1, y1 be Element of A st A is Subring of B &
	x = x1 & y = y1 holds x + y = x1 + y1
	proof
	let x, y be Element of B,
	x1, y1 be Element of A;
	assume A is Subring of B; then
	the addF of A = (the addF of B) \|\| the carrier of A by C0SP1:def 3;
	hence thesis by FUNCT_1:49,ZFMISC_1:87;
	end;

	theorem Th9:
	for x, y be Element of B, x1, y1 be Element of A st
	A is Subring of B & x = x1 & y = y1 holds x * y = x1 * y1
	proof
	let x, y be Element of B, x1, y1 be Element of A;
	assume A is Subring of B; then
	the multF of A = (the multF of B) \|\| the carrier of A by C0SP1:def 3;
	hence thesis by FUNCT_1:49,ZFMISC_1:87;
	end;

	registration
	let c be Complex;
	reduce In(c,F_Complex) to c;
	reducibility
	proof
	c in COMPLEX by XCMPLX_0:def 2;
	then c is Element of F_Complex by COMPLFLD:def 1;
	hence thesis by SUBSET_1:def 8;
	end;
	end;

	begin
	:: Define Extended eval Function for commutative rings A c= B
	:: based upon POLYNOM4

	definition
	let A,B be Ring;
	let p be Polynomial of A;
	let x be Element of B;
	func Ext_eval(p,x) -> Element of B means
	:Def1:
	ex F be FinSequence of B st it = Sum F & len F = len p
	& for n be Element of NAT st n in dom F holds
	F.n = In(p.(n-'1),B) * (power B).(x,n-'1);
	existence
	proof
	deffunc G(Nat) = In(p.($1-'1),B)*(power B).(x,$1-'1);
	consider F be FinSequence of B such that
	A1: len F = len p and
	A2: for n be Nat st n in dom F holds F.n = G(n) from FINSEQ_2:sch 1;
	take y = Sum F;
	take F;
	thus y = Sum F & len F = len p by A1;
	let n be Element of NAT;
	assume n in dom F;
	hence thesis by A2;
	end;
	uniqueness
	proof
	let y1,y2 be Element of B;
	given F1 be FinSequence of B such that
	A3: y1 = Sum F1 and
	A4: len F1 = len p and
	A5: for n be Element of NAT st n in dom F1 holds
	F1.n = In(p.(n-'1),B)*(power B).(x,n-'1);
	given F2 be FinSequence of B such that
	A6: y2 = Sum F2 and
	A7: len F2 = len p and
	A8: for n be Element of NAT st n in dom F2 holds
	F2.n = In(p.(n-'1),B)*(power B).(x,n-'1);
	A9: dom F1 = Seg len p by A4,FINSEQ_1:def 3;
	now
	let n be Nat;
	assume
	A10: n in dom F1; then
	A11: n in dom F2 by A7,A9,FINSEQ_1:def 3;
	thus F1.n = In(p.(n-'1),B) *(power B).(x,n-'1) by A5,A10
	.= F2.n by A8,A11;
	end;
	hence thesis by A3,A4,A6,A7,FINSEQ_2:9;
	end;
	end;

	theorem Th11:
	for n being Element of NAT, A,B be Ring, z be Element of A st
	A is Subring of B holds
	(power B).(In(z,B),n) = In((power A).(z,n),B)
	proof
	let n be Element of NAT, A,B be Ring, z be Element of A;
	assume
	A0: A is Subring of B; then
	z is Element of B by Lm6; then
	A2: In(z,B) = z by SUBSET_1:def 8;
	A3: 1_A = 1_B by A0,C0SP1:def 3;
	reconsider x = z as Element of B by A0,Lm6;
	(power B).(In(z,B),n) = In((power A).(z,n),B)
	proof
	defpred P[Nat] means (power B).(In(z,B),$1) = In((power A).(z,$1),B);
	A5: P[0]
	proof
	A6: In(1.A,B) = 1.B by A0,Lm5;
	In((power A).(z,0),B) = 1.B by A3,GROUP_1:def 7,A6;
	hence thesis by A3,GROUP_1:def 7;
	end;
	A7: for m be Nat st P[m] holds P[m+1]
	proof
	let m be Nat;
	assume
	A9: P[m];
	A10: (power A).(z,m) is Element of B by A0,Lm6;
	A11: In((power A).(z,m),B) = (power A).(z,m)
	by A10,SUBSET_1:def 8;
	A12: (power A).(z,m+1) is Element of B by A0,Lm6;
	(power B).(In(z,B),m+1)
	= (power B).(In(z,B),m)* In(z,B) by GROUP_1:def 7
	.= (power A).(z,m)*z by A0,A11,A2,Th9,A9
	.= (power A).(z,m+1) by GROUP_1:def 7
	.= In((power A).(z,m+1),B) by A12,SUBSET_1:def 8;
	hence thesis;
	end;
	for m be Nat holds P[m] from NAT_1:sch 2(A5,A7);
	hence thesis;
	end;
	hence thesis;
	end;

	theorem Th12:
	for x1,x2 be Element of A st A is Subring of B holds
	In(x1,B) + In(x2,B) = In(x1+x2,B)
	proof
	let x1,x2 be Element of A;
	assume
	A0: A is Subring of B; then
	x1 is Element of B by Lm6; then
	A2: In(x1,B) = x1 by SUBSET_1:def 8;
	x2 is Element of B by A0,Lm6; then
	A4: In(x2,B) = x2 by SUBSET_1:def 8;
	x1 + x2 is Element of B by A0,Lm6; then
	In(x1+x2,B) = x1+x2 by SUBSET_1:def 8
	.= In(x1,B)+In(x2,B) by A0,A2,A4,Th8;
	hence thesis;
	end;

	theorem Th13:
	for x1,x2 be Element of A st A is Subring of B holds
	In(x1,B) * In(x2,B) = In(x1*x2,B)
	proof
	let x1,x2 be Element of A;
	assume
	A0: A is Subring of B; then
	x1 is Element of B by Lm6; then
	A2: In(x1,B) = x1 by SUBSET_1:def 8;
	x2 is Element of B by A0,Lm6; then
	A4: In(x2,B) = x2 by SUBSET_1:def 8;
	x1*x2 is Element of B by A0,Lm6; then
	In(x1x2,B) = x1x2 by SUBSET_1:def 8
	.= In(x1,B)*In(x2,B) by A0,A2,A4,Th9;
	hence thesis;
	end;

	theorem Th14:
	for F be FinSequence of A,
	G be FinSequence of B
	st A is Subring of B & F = G holds In(Sum F,B) = Sum G
	proof
	let F be FinSequence of A, G be FinSequence of B;
	assume
	A0: A is Subring of B;
	defpred P[Nat] means
	for F being FinSequence of A, G being FinSequence of B
	st len F = $1 & F = G holds In(Sum F,B) = Sum G;
	P1: P[0]
	proof
	let F be FinSequence of A,
	G be FinSequence of B;
	assume
	A1: len F = 0 & F = G; then
	A2: F = <*>the carrier of A;
	A3: G = <*>the carrier of B by A1;
	In(Sum F,B) = In(0.A,B) by A2,RLVECT_1:43
	.= In(0.B,B) by A0,C0SP1:def 3 .= 0.B by SUBSET_1:def 8
	.= Sum G by A3,RLVECT_1:43;
	hence thesis;
	end;
	P2: for n being Nat st P[n] holds P[n+1]
	proof
	let n be Nat;
	assume
	A4: P[n];
	let F be FinSequence of A,
	G be FinSequence of B;
	assume
	A5: len F = n+1 & F = G;
	reconsider F0 = F\| n as FinSequence of A;
	n+1 in Seg (n+1) by FINSEQ_1:4; then
	A6: n+1 in dom F by A5,FINSEQ_1:def 3;
	rng F c= the carrier of A; then
	reconsider af = F.(n+1) as Element of A by A6,FUNCT_1:3;
	A7: len F0 = n by FINSEQ_1:59,A5,NAT_1:11;
	A8: len F = (len F0) + 1 by A5,FINSEQ_1:59,NAT_1:11;
	A9: F0 = F \| dom F0 by A7,FINSEQ_1:def 3;
	reconsider G0 = G\| n as FinSequence of B;
	n+1 in Seg (n+1) by FINSEQ_1:4; then
	A10: n+1 in dom G by A5,FINSEQ_1:def 3;
	rng G c= the carrier of B; then
	reconsider bf = G.(n+1) as Element of B by A10,FUNCT_1:3;
	A11: len F0 = n & F0 = G0 by FINSEQ_1:59,A5,NAT_1:11;
	G = G0^<bf> by A5,FINSEQ_3:55; then
	Sum G = Sum G0 + bf by FVSUM_1:71
	.= In(Sum F0,B)+ bf by A4,A11
	.= In(Sum F0,B) + In(af,B) by A5,SUBSET_1:def 8
	.= In(Sum F0 + af,B) by A0,Th12
	.= In(Sum F,B) by A5,A8,A9,RLVECT_1:38;
	hence thesis;
	end;
	for n being Nat holds P[n] from NAT_1:sch 2(P1,P2);
	hence thesis;
	end;

	theorem Th15:
	for n be Nat, x be Element of A, p be Polynomial of A st A is Subring of B
	holds In(p.(n-'1),B)*(power B).(In(x,B),n-'1)
	= In(p.(n-'1) * (power A).(x,n-'1),B)
	proof
	let n be Nat,x be Element of A, p be Polynomial of A;
	assume
	A0: A is Subring of B; then
	In(p.(n-'1) * (power A).(x,n-'1),B)
	= In(p.(n-'1),B)*In((power A).(x,n-'1),B) by Th13
	.= In(p.(n-'1),B)*(power B).(In(x,B),n -'1) by A0,Th11;
	hence thesis;
	end;

	theorem Th16:
	for x be Element of A, p be Polynomial of A st A is Subring of B holds
	Ext_eval(p,In(x,B)) = In(eval(p,x),B)
	proof
	let x be Element of A, p be Polynomial of A;
	assume
	A0: A is Subring of B;
	consider F1 be FinSequence of B such that
	A1: Ext_eval(p,In(x,B)) = Sum F1 and
	A2: len F1 = len p and
	A3: for n be Element of NAT st n in dom F1 holds
	F1.n = In(p.(n-'1),B) * (power B).(In(x,B),n-'1) by Def1;
	consider F2 be FinSequence of A such that
	A4: eval(p,x) = Sum F2 and
	A5: len F2 = len p and
	A6: for n be Element of NAT st n in dom F2 holds
	F2.n = p.(n-'1) * (power A).(x,n-'1) by POLYNOM4:def 2;
	F1 = F2
	proof
	A11: rng F2 c= the carrier of A;
	A8: dom F1 = dom F2 by A2,A5,FINSEQ_3:29;
	for k be Nat st k in dom F1 holds F1.k = F2.k
	proof
	let k be Nat;
	assume
	A10: k in dom F1; then
	F2.k is Element of A by A8,FUNCT_1:3,A11; then
	A13: F2.k is Element of B by A0,Lm6;
	F1.k = In(p.(k-'1),B) * (power B).(In(x,B),k-'1) by A3,A10
	.= In(p.(k-'1) * (power A).(x,k-'1),B) by A0,Th15
	.= In(F2.k,B) by A6,A10,A8
	.= F2.k by A13,SUBSET_1:def 8;
	hence thesis;
	end;
	hence thesis by A2,A5,FINSEQ_3:29;
	end;
	hence thesis by A1,A4,A0,Th14;
	end;

	:: Modify POLYNOM4:17
	theorem Th17:
	for x be Element of B holds Ext_eval(0_.A,x) = 0.B
	proof
	let x be Element of B;
	consider F be FinSequence of B such that
	A1: Ext_eval(0_.A,x) = Sum F and
	A2: len F = len 0_.A and
	for n be Element of NAT st n in dom F holds
	F.n = In((0_.A).(n-'1),B) * (power B).(x,n-'1) by Def1;
	F = <*>the carrier of B by A2,POLYNOM4:3;
	hence thesis by A1,RLVECT_1:43;
	end;

	:: Modify POLYNOM4:18
	theorem Th18:
	for A,B being non degenerated Ring
	for x be Element of B st A is Subring of B holds
	Ext_eval(1_.A,x) = 1.B
	proof
	let A,B be non degenerated Ring;
	let x be Element of B;
	assume
	A0: A is Subring of B;
	consider F be FinSequence of B such that
	A1: Ext_eval(1_.A,x) = Sum F and
	A2: len F = len 1_.A and
	A3: for n be Element of NAT st n in dom F holds
	F.n = In((1_.A).(n-'1),B)*(power B).(x,n-'1) by Def1;
	len F = 1 by A2,POLYNOM4:4; then
	A4: F.1 = In((1_.A).(1-'1),B) * (power B).(x,1-'1) by A3,FINSEQ_3:25
	.= In((1_.A).(0),B) * (power B).(x,1-'1) by XREAL_1:232
	.= In(1.A,B) * (power B).(x,1-'1) by POLYNOM3:30
	.= 1.B * (power B).(x,1-'1) by A0,Lm5
	.= (power B).(x,0) by XREAL_1:232 .= 1_B by GROUP_1:def 7 .= 1.B;
	Sum F = Sum <1.B> by A2,POLYNOM4:4,FINSEQ_1:40,A4 .= 1.B by RLVECT_1:44;
	hence thesis by A1;
	end;

	:: Modify POLYNOM4:19
	theorem Th19:
	for x be Element of B, p,q be Polynomial of A st A is Subring of B holds
	Ext_eval(p+q,x) = Ext_eval(p,x) + Ext_eval(q,x)
	proof
	let x be Element of B, p,q be Polynomial of A;
	assume
	A0: A is Subring of B;
	reconsider k = max(len p,len q) as Element of NAT;
	A1: k - len p >= 0 by XREAL_1:48,XXREAL_0:25;
	consider F1 be FinSequence of B such that
	A2: Ext_eval(p,x) = Sum F1 and
	A3: len F1 = len p and
	A4: for n be Element of NAT st n in dom F1 holds
	F1.n = In(p.(n-'1),B) * (power B).(x,n-'1) by Def1;
	A5: len (F1 ^ ((k-'(len F1)) \|-> 0.B))
	= len p + len ((k-'(len p)) \|-> 0.B) by A3,FINSEQ_1:22
	.= len p + (k-'(len p)) by CARD_1:def 7
	.= len p + (k-(len p)) by A1,XREAL_0:def 2 .= k;
	A6: k - len q >= 0 by XREAL_1:48,XXREAL_0:25;
	k >= len p & k >= len q by XXREAL_0:25; then
	A7: k - len (p+q) >= 0 by POLYNOM4:6,XREAL_1:48;
	consider F3 be FinSequence of B such that
	A8: Ext_eval(p+q,x) = Sum F3 and
	A9: len F3 = len (p+q) and
	A10: for n be Element of NAT st n in dom F3 holds
	F3.n = In((p+q).(n-'1),B) * (power B).(x,n-'1) by Def1;
	A11: len (F3 ^ ((k-'(len F3)) \|-> 0.B))
	= len F3 + len((k-'(len F3)) \|-> 0.B) by FINSEQ_1:22
	.= len (p+q) + (k-'(len (p+q))) by CARD_1:def 7,A9
	.= len (p+q) + (k-(len (p+q))) by A7,XREAL_0:def 2
	.= k;
	consider F2 be FinSequence of B such that
	A12: Ext_eval(q,x) = Sum F2 and
	A13: len F2 = len q and
	A14: for n be Element of NAT st n in dom F2 holds
	F2.n = In(q.(n-'1),B) * (power B).(x,n-'1) by Def1;
	len (F2 ^ ((k-'(len F2)) \|-> 0.B))
	= len q + len ((k-'(len q)) \|-> 0.B) by A13,FINSEQ_1:22
	.= len q + (k-'(len q)) by CARD_1:def 7
	.= len q + (k-(len q)) by A6,XREAL_0:def 2 .= k;
	then reconsider
	G1 = F1 ^ ((k-'(len F1)) \|-> 0.B), G2 = F2 ^ ((k-'(len F2)) \|->
	0.B), G3 = F3 ^ ((k-'(len F3)) \|-> 0.B)
	as Element of k-tuples_on the carrier of B by A5,A11,FINSEQ_2:92;
	now
	let n be Nat;
	assume
	A15: n in Seg k; then
	A16: 0+1 <= n by FINSEQ_1:1;
	A17: n <= k by A15,FINSEQ_1:1;
	per cases by XXREAL_0:1;
	suppose
	A18: len p > len q; then
	k = len p by XXREAL_0:def 10; then
	len(p+q) = len p by A18,POLYNOM4:7; then
	A20: n in dom F3 by A9,A15,A18,XXREAL_0:def 10,FINSEQ_1:def 3;
	A21: len G2 = k by CARD_1:def 7; then
	A22: n in dom G2 by A15,FINSEQ_1:def 3; then
	A23: G2/.n = G2.n by PARTFUN1:def 6;
	len G1 = k by CARD_1:def 7; then
	A24: n in dom G1 by A15,FINSEQ_1:def 3; then
	A25: G1/.n = G1.n by PARTFUN1:def 6;
	A26: n in dom F1 by A3,A15,A18,XXREAL_0:def 10,FINSEQ_1:def 3;
	A27: G1/.n = G1.n by A24,PARTFUN1:def 6 .= F1.n by A26,FINSEQ_1:def 7
	.= F1/.n by A26,PARTFUN1:def 6;
	A28: F1.n = In(p.(n-'1),B)*(power B).(x,n-'1) by A4,A26;
	now
	per cases;
	suppose
	n <= len q; then
	A29: n in dom F2 by A16,A13,FINSEQ_3:25; then
	A30: F2.n = In(q.(n-'1),B)*(power B).(x,n-'1) by A14;
	A31: G2/.n = G2.n by A22,PARTFUN1:def 6 .= F2.n by A29,FINSEQ_1:def 7
	.= F2/.n by A29,PARTFUN1:def 6;
	thus G3.n = F3.n by A20,FINSEQ_1:def 7
	.= In((p+q).(n-'1),B)*(power B).(x,n-'1) by A10,A20
	.= In((p.(n-'1) + q.(n-'1)),B)
	* (power B).(x,n-'1) by NORMSP_1:def 2
	.= ( In (p.(n-'1),B) + In( q.(n-'1),B))
	* (power B).(x,n-'1) by A0,Th12
	.= In(p.(n-'1),B)*(power B).(x,n-'1)
	+ In(q.(n-'1),B)*(power B).(x,n-'1) by VECTSP_1:def 3
	.= In(p.(n-'1),B)*(power B).(x,n-'1)
	+ F2/.n by A29,A30,PARTFUN1:def 6
	.= F1/.n + F2/.n by A26,A28,PARTFUN1:def 6
	.= (G1 + G2).n by A15,A25,A23,A27,A31,FVSUM_1:18;
	end;
	suppose
	A32: n > len q; then
	A33: n >= len q+1 by NAT_1:13; then
	n-1 >= len q by XREAL_1:19; then
	A34: n-'1 >= len q by XREAL_0:def 2;
	n-len F2 <= k-len F2 by A17,XREAL_1:9; then
	A35: n-len F2 <= k-'len F2 by XREAL_0:def 2;
	A36: n-len F2 >= 1 by A13,A33,XREAL_1:19; then
	n-len F2 = n-'len F2 by XREAL_0:def 2; then
	A37: n-len F2 in Seg (k-'len F2) by A36,A35;
	n <= len G2 by A15,A21,FINSEQ_1:1; then
	A38: G2/.n = ((k-'(len F2)) \|-> 0.B).(n - len F2)
	by A13,A23,A32,FINSEQ_1:24 .= 0.B by A37,FUNCOP_1:7;
	thus G3.n = F3.n by A20,FINSEQ_1:def 7
	.= In((p+q).(n-'1),B) * (power B).(x,n-'1) by A10,A20
	.= In(p.(n-'1) + q.(n-'1),B) * (power B).(x,n-'1)
	by NORMSP_1:def 2
	.= In(p.(n-'1) + 0.A,B) * (power B).(x,n-'1) by A34,ALGSEQ_1:8
	.= F1.n by A4,A26 .= G1/.n + 0.B by A26,A27,PARTFUN1:def 6
	.= (G1 + G2).n by A15,A25,A23,A38,FVSUM_1:18;
	end;
	end;
	hence G3.n = (G1 + G2).n;
	end;
	suppose
	A39: len p < len q; then
	k = len q by XXREAL_0:def 10; then
	len(p+q) = len q by A39,POLYNOM4:7; then
	A41: n in dom F3 by A9,A15,A39,XXREAL_0:def 10,FINSEQ_1:def 3;
	A42: len G1 = k by CARD_1:def 7; then
	A43: n in dom G1 by A15,FINSEQ_1:def 3; then
	A44: G1/.n = G1.n by PARTFUN1:def 6;
	len G2 = k by CARD_1:def 7; then
	A45: n in dom G2 by A15,FINSEQ_1:def 3; then
	A46: G2/.n = G2.n by PARTFUN1:def 6;
	A47: n in dom F2 by A13,A15,A39,XXREAL_0:def 10,FINSEQ_1:def 3;
	A48: G2/.n = G2.n by A45,PARTFUN1:def 6 .= F2.n by A47,FINSEQ_1:def 7
	.= F2/.n by A47,PARTFUN1:def 6;
	A49: F2.n = In(q.(n-'1),B)*(power B).(x,n-'1) by A14,A47;
	now
	per cases;
	suppose n <= len p; then
	A50: n in dom F1 by A16,A3,FINSEQ_3:25; then
	A51: F1.n = In(p.(n-'1),B)*(power B).(x,n-'1) by A4;
	A52: G1/.n = G1.n by A43,PARTFUN1:def 6 .= F1.n by A50,FINSEQ_1:def 7
	.= F1/.n by A50,PARTFUN1:def 6;
	thus G3.n = F3.n by A41,FINSEQ_1:def 7
	.= In((p+q).(n-'1),B) * (power B).(x,n-'1) by A10,A41
	.= In(p.(n-'1) + q.(n-'1),B) * (power B).(x,n-'1)
	by NORMSP_1:def 2
	.= ( In (p.(n-'1),B) + In( q.(n-'1),B))
	* (power B).(x,n-'1) by A0,Th12
	.= In(p.(n-'1),B)*(power B).(x,n-'1)
	+ In(q.(n-'1),B)*(power B).(x,n-'1) by VECTSP_1:def 3
	.= F1/.n + In(q.(n-'1),B)*(power B).(x,n-'1)
	by A50,A51,PARTFUN1:def 6
	.= F1/.n + F2/.n by A47,A49,PARTFUN1:def 6
	.= (G1 + G2).n by A15,A44,A46,A48,A52,FVSUM_1:18;
	end;
	suppose
	A53: n > len p; then
	A54: n >= len p+1 by NAT_1:13;then
	n-1 >= len p by XREAL_1:19; then
	A55: n-'1 >= len p by XREAL_0:def 2;
	n-len F1 <= k-len F1 by A17,XREAL_1:9; then
	A56: n-len F1 <= k-'len F1 by XREAL_0:def 2;
	A57: n-len F1 >= 1 by A3,A54,XREAL_1:19; then
	n-len F1 = n-'len F1 by XREAL_0:def 2; then
	A58: n-len F1 in Seg (k-'len F1) by A57,A56;
	n <= len G1 by A15,A42,FINSEQ_1:1; then
	A59: G1/.n = ((k-'(len F1)) \|-> 0.B).(n-len F1) by A3,A44,A53,FINSEQ_1:24
	.= 0.B by A58,FUNCOP_1:7;
	thus G3.n = F3.n by A41,FINSEQ_1:def 7
	.= In((p+q).(n-'1),B)*(power B).(x,n-'1) by A10,A41
	.= In(p.(n-'1) + q.(n-'1),B) * (power B).(x,n-'1) by NORMSP_1:def 2
	.= In(0.A + q.(n-'1),B) * (power B).(x,n-'1) by A55,ALGSEQ_1:8
	.= F2.n by A14,A47
	.= 0.B + G2/.n by A47,A48,PARTFUN1:def 6
	.= (G1 + G2).n by A15,A44,A46,A59,FVSUM_1:18;
	end;
	end;
	hence G3.n = (G1 + G2).n;
	end;
	suppose
	A60: len p = len q;
	len G2 = k by CARD_1:def 7; then
	A61: n in dom G2 by A15,FINSEQ_1:def 3; then
	A62: G2/.n = G2.n by PARTFUN1:def 6;
	len G1 = k by CARD_1:def 7; then
	A63: n in dom G1 by A15,FINSEQ_1:def 3; then
	A64: G1/.n = G1.n by PARTFUN1:def 6;
	A65: len G3 = k by CARD_1:def 7;
	A66: n in dom F2 by A13,A15,A60,FINSEQ_1:def 3;
	A67: n in dom F1 by A3,A15,A60,FINSEQ_1:def 3; then
	A68: F1.n = In(p.(n-'1),B)*(power B).(x,n-'1) by A4;
	A69: G1/.n = G1.n by A63,PARTFUN1:def 6 .= F1.n by A67,FINSEQ_1:def 7
	.= F1/.n by A67,PARTFUN1:def 6;
	now
	per cases;
	suppose
	A70: n <= len (p+q);
	A71: n in dom F2 by A13,A15,A60,FINSEQ_1:def 3; then
	A72: F2.n = In(q.(n-'1),B)*(power B).(x,n-'1) by A14;
	A73: G2/.n = G2.n by A61,PARTFUN1:def 6 .= F2.n by A71,FINSEQ_1:def 7
	.= F2/.n by A71,PARTFUN1:def 6;
	n in Seg len (p+q) by A16,A70; then
	A74: n in dom F3 by A9,FINSEQ_1:def 3;
	hence G3.n = F3.n by FINSEQ_1:def 7
	.= In((p+q).(n-'1),B) * (power B).(x,n-'1) by A10,A74
	.= In(p.(n-'1) + q.(n-'1),B)*(power B).(x,n-'1) by NORMSP_1:def 2
	.= ( In (p.(n-'1),B) + In( q.(n-'1),B))
	* (power B).(x,n-'1) by A0,Th12
	.= In(p.(n-'1),B)*(power B).(x,n-'1)
	+ In(q.(n-'1),B)*(power B).(x,n-'1) by VECTSP_1:def 3
	.= In(p.(n-'1),B)*(power B).(x,n-'1) + F2/.n
	by A71,A72,PARTFUN1:def 6
	.= F1/.n + F2/.n by A67,A68,PARTFUN1:def 6
	.= (G1 + G2).n by A15,A64,A62,A69,A73,FVSUM_1:18;
	end;
	suppose
	A75: n > len (p+q); then
	A76: n >= len (p+q)+1 by NAT_1:13; then
	n-1 >= len (p+q)+1-1 by XREAL_1:9; then
	A77: n-'1 >= len (p+q) by XREAL_0:def 2;
	n-len F3 <= k-len F3 by A17,XREAL_1:9; then
	A78: n-len F3 <= k-'len F3 by XREAL_0:def 2;
	A79: G2.n = F2.n by A66,FINSEQ_1:def 7
	.= In(q.(n-'1),B)*(power B).(x,n-'1) by A14,A66;
	A80: G1.n = F1.n by A67,FINSEQ_1:def 7
	.= In(p.(n-'1),B)*(power B).(x,n-'1) by A4,A67;
	A81: n-len F3 >= 1 by A9,A76,XREAL_1:19; then
	n-len F3 = n-'len F3 by XREAL_0:def 2; then
	A82: n-len F3 in Seg (k-'len F3) by A81,A78;
	n <= len G3 by A15,A65,FINSEQ_1:1;
	hence
	G3.n=((k-'(len F3)) \|-> 0.B).(n-len F3) by A9,A75,FINSEQ_1:24
	.= 0.B * (power B).(x,n-'1) by A82,FUNCOP_1:7
	.= In(0.A,B)*(power B).(x,n-'1) by A0,Lm5
	.= In((p+q).(n-'1),B) * (power B).(x,n-'1) by A77,ALGSEQ_1:8
	.= In(p.(n-'1) + q.(n-'1),B) * (power B).(x,n-'1) by NORMSP_1:def 2
	.= ( In (p.(n-'1),B) + In( q.(n-'1),B))
	* (power B).(x,n-'1) by A0,Th12
	.= In(p.(n-'1),B)*(power B).(x,n-'1)
	+ In(q.(n-'1),B)*(power B).(x,n-'1) by VECTSP_1:def 3
	.= (G1 + G2).n by A15,A80,A79,FVSUM_1:18;
	end;
	end;
	hence G3.n = (G1 + G2).n;
	end;
	end;
	then
	A83: G3 = G1 + G2 by FINSEQ_2:119;
	A84: Sum G3 = Sum F3 + Sum ((k-'(len F3)) \|-> 0.B) by RLVECT_1:41
	.= Sum F3 + 0.B by MATRIX_3:11 .= Sum F3;
	A85: Sum G2 = Sum F2 + Sum ((k-'(len F2)) \|-> 0.B) by RLVECT_1:41
	.= Sum F2 + 0.B by MATRIX_3:11 .= Sum F2;
	Sum G1 = Sum F1 + Sum ((k-'(len F1)) \|-> 0.B) by RLVECT_1:41
	.= Sum F1 + 0.B by MATRIX_3:11 .= Sum F1;
	hence thesis by A2,A12,A8,A85,A84,A83,FVSUM_1:76;
	end;

	theorem Th20:
	for p,q be Polynomial of A st A is Subring of B & len p > 0 & len q > 0
	for x be Element of B holds
	Ext_eval((Leading-Monomial(p))*'(Leading-Monomial(q)),x)
	= In(p.(len p-'1)q.(len q-'1),B)(power B).(x,len p+len q-'2)
	proof
	let p,q be Polynomial of A;
	assume that
	A0: A is Subring of B and
	A1: len p > 0 and
	A2: len q > 0;
	A3: len q >= 0+1 by A2,NAT_1:13;
	A5: len p >= 0+1 by A1,NAT_1:13;
	A6: len p-1 = len p-'1 by A1,XREAL_0:def 2;
	A7: len p + len q >= 0+(1+1) by A5,A3,XREAL_1:7;
	reconsider i1=len p + len q - 1 as Element of NAT by A1,INT_1:3;
	A9: i1-'1+1 = i1 by A7,XREAL_1:19,XREAL_1:235;
	set LMp=Leading-Monomial(p), LMq=Leading-Monomial(q);
	let x be Element of B;
	consider F be FinSequence of B such that
	A10: Ext_eval(LMp*'LMq,x) = Sum F and
	A11: len F = len (LMp*'LMq) and
	A12: for n be Element of NAT st n in dom F holds
	F.n=In((LMp'LMq).(n-'1),B)(power B).(x,n-'1) by Def1;
	consider r be FinSequence of A such that
	A13: len r = i1-'1+1 and
	A14: (LMp*'LMq).(i1-'1) = Sum r and
	A15: for k be Element of NAT st k in dom r holds
	r.k = LMp.(k-'1)*LMq.(i1-'1+1-'k) by POLYNOM3:def 9;
	len p+0 <= len p+(len q-1) by A2,XREAL_1:7; then
	len p in Seg len r by A5,A9,A13; then
	A16: len p in dom r by FINSEQ_1:def 3;
	i1-'len p = len p+(len q-1)-len p by A2,XREAL_0:def 2
	.= len q-'1 by A2,XREAL_0:def 2; then
	A17: r.(len p) = LMp.(len p-'1) * LMq.(len q-'1) by A9,A15,A16;
	now
	let i be Element of NAT;
	assume that
	A18: i in dom r and
	A19: i <> len p;
	i >= 0+1 by A18,FINSEQ_3:25; then
	i-'1 = i-1 by XREAL_0:def 2; then
	A20: i-'1 <> len p-'1 by A6,A19;
	thus r/.i = r.i by A18,PARTFUN1:def 6
	.= LMp.(i-'1) * LMq.(i1-'1+1-'i) by A15,A18
	.= 0.A*LMq.(i1-'1+1-'i) by A20,POLYNOM4:def 1 .= 0.A;
	end;
	then
	A21: Sum r = r/.(len p) by A16,POLYNOM2:3
	.= LMp.(len p-'1) * LMq.(len q-'1) by A16,A17,PARTFUN1:def 6
	.= p.(len p-'1) * LMq.(len q-'1) by POLYNOM4:def 1
	.= p.(len p-'1) * q.(len q-'1) by POLYNOM4:def 1;
	A22: len q-1 = len q-'1 by A2,XREAL_0:def 2;
	A23: now
	let i be Element of NAT;
	assume that
	A24: i in dom F and
	A25: i <> i1;
	consider r1 be FinSequence of A such that
	A26: len r1 = i-'1+1 and
	A27: (LMp*'LMq).(i-'1) = Sum r1 and
	A28: for k be Element of NAT st k in dom r1 holds r1.k=LMp.(k-'1)*LMq.
	(i-'1+1-'k) by POLYNOM3:def 9;
	A29: i-'1+1 = i by A24,FINSEQ_3:25,XREAL_1:235;
	A30: now
	let j be Element of NAT;
	assume
	A31: j in dom r1; then
	j >= 0+1 by FINSEQ_3:25; then
	A32: j-'1 = j-1 by XREAL_0:def 2;
	per cases;
	suppose
	j<>len p; then
	A33: j-'1 <> len p-'1 by A6,A32;
	thus r1.j = LMp.(j-'1)*LMq.(i-'1+1-'j) by A28,A31
	.= 0.A*LMq.(i-'1+1-'j) by A33,POLYNOM4:def 1
	.= 0.A;
	end;
	suppose
	A34: j=len p;
	j in Seg len r1 by A31,FINSEQ_1:def 3; then
	i >= 0+j by A26,A29,FINSEQ_1:1; then
	i-'len p = i-len p by A34,XREAL_1:19,XREAL_0:def 2; then
	A35: i-'len p <> len q-'1 by A22,A25;
	thus r1.j = LMp.(j-'1)*LMq.(i-'len p) by A28,A29,A31,A34
	.= LMp.(j-'1)*0.A by A35,POLYNOM4:def 1 .= 0.A;
	end;
	end;
	thus F/.i = F.i by A24,PARTFUN1:def 6
	.= In(Sum r1,B)*(power B).(x,i-'1) by A12,A24,A27
	.= In(0.A,B)*(power B).(x,i-'1) by A30,POLYNOM3:1
	.= 0.B*(power B).(x,i-'1) by A0,Lm5
	.= 0.B;
	end;
	A36: len p+len q-2 >= 0 by A7,XREAL_1:19;
	len p+len q-(1+1) >= 0 by A7,XREAL_1:19; then
	A37: i1-'1 = len p+len q-1-1 by XREAL_0:def 2
	.= len p+len q-'2 by A36,XREAL_0:def 2;
	per cases;
	suppose (LMp*'LMq).(i1-'1) <> 0.A; then
	len F >= i1 by A11,ALGSEQ_1:8,A9,NAT_1:13; then
	A38: i1 in dom F by A7,XREAL_1:19,FINSEQ_3:25;
	hence Ext_eval((Leading-Monomial(p))*'(Leading-Monomial(q)),x)
	= F/.i1 by A10,A23,POLYNOM2:3
	.= F.i1 by A38,PARTFUN1:def 6
	.= In(p.(len p-'1)*q.(len q-'1),B)
	*(power B).(x,len p+len q-'2) by A12,A14,A37,A21,A38;
	end;
	suppose
	A39: (LMp*'LMq).(i1-'1) = 0.A;
	now
	let j be Nat;
	assume j >= 0;
	j in NAT by ORDINAL1:def 12;
	then consider r1 be FinSequence of A such that
	A40: len r1 = j+1 and
	A41: (LMp*'LMq).j = Sum r1 and
	A42: for k be Element of NAT st k in dom r1 holds r1.k = LMp.(k-'1)*
	LMq.(j+1-'k) by POLYNOM3:def 9;
	now
	per cases;
	suppose
	j = i1-'1;
	hence (LMp*'LMq).j = 0.A by A39;
	end;
	suppose
	A43: j <> i1-'1;
	now
	let k be Element of NAT;
	assume
	A44: k in dom r1;
	per cases;
	suppose
	A45: k-'1 <> len p-'1;
	thus r1.k = LMp.(k-'1)*LMq.(j+1-'k) by A42,A44
	.= 0.A*LMq.(j+1-'k) by A45,POLYNOM4:def 1 .= 0.A;
	end;
	suppose
	A46: k-'1 = len p-'1;
	A47: k in Seg len r1 by A44,FINSEQ_1:def 3;
	0+1 <= k by A44,FINSEQ_3:25; then
	A48: k-'1 = k-1 by XREAL_0:def 2;
	0+k <= j+1 by A40,A47,FINSEQ_1:1; then
	j+1-k >= 0 by XREAL_1:19; then
	A49: j+1-'k = j-len p+1 by A6,A46,A48,XREAL_0:def 2;
	A50: j-len p+1 <> i1-'1-len p+1 by A43;
	thus r1.k = LMp.(k-'1)*LMq.(j+1-'k) by A42,A44
	.= LMp.(k-'1)*0.A by A22,A9,A49,A50,POLYNOM4:def 1
	.= 0.A;
	end;
	end;
	hence (LMp*'LMq).j = 0.A by A41,POLYNOM3:1;
	end;
	end;
	hence (LMp*'LMq).j = 0.A;
	end; then
	0 is_at_least_length_of (LMp*'LMq); then
	len (LMp*'LMq) = 0 by ALGSEQ_1:def 3; then
	A52: LMp*'LMq = 0_.A by POLYNOM4:5;
	0.B = In(p.(len p-'1) * q.(len q-'1),B)
	by A0,Lm5,A21,A14,A39;
	hence thesis by Th17,A52;
	end;
	end;

	theorem Th21:
	for p be Polynomial of A for x be Element of B st A is Subring of B holds
	Ext_eval(Leading-Monomial(p),x)
	= In(p.(len p-'1),B) * (power B).(x,len p-'1)
	proof
	let p be Polynomial of A;
	let x be Element of B;
	assume
	A0: A is Subring of B;
	set LMp=Leading-Monomial(p);
	consider F be FinSequence of B such that
	A1: Ext_eval(LMp,x) = Sum F and
	A2: len F = len LMp and
	A3: for n be Element of NAT st n in dom F holds
	F.n = In(LMp.(n-'1),B)*(power B).(x,n-'1) by Def1;
	A4: len F = len p by A2,POLYNOM4:15;
	per cases;
	suppose
	A5: len p > 0; then
	A7: len p >= 0+1 by NAT_1:13; then
	A6: len p in dom F by A4,FINSEQ_3:25;
	now
	A8: len p-'1 = len p-1 by A5,XREAL_0:def 2;
	let i be Element of NAT;
	assume that
	A9: i in dom F and
	A10: i <> len p;
	i >= 0+1 by A9,FINSEQ_3:25; then
	i-'1 = i-1 by XREAL_0:def 2; then
	A11: i-'1 <> len p-'1 by A10,A8;
	thus F/.i = F.i by A9,PARTFUN1:def 6
	.= In(LMp.(i-'1),B)*(power B).(x,i-'1) by A3,A9
	.= In(0.A,B)*(power B).(x,i-'1) by A11,POLYNOM4:def 1
	.= 0.B *(power B).(x,i-'1) by A0,Lm5
	.= 0.B;
	end;
	then Sum F = F/.(len p) by A4,A7,FINSEQ_3:25,POLYNOM2:3
	.= F.(len p) by A6,PARTFUN1:def 6
	.= In(LMp.(len p-'1),B)*(power B).(x,len p-'1) by A3,A7,A4,FINSEQ_3:25;
	hence thesis by A1,POLYNOM4:def 1;
	end;
	suppose
	A12: len p = 0; then
	A13: p = 0_.A by POLYNOM4:5;
	LMp = 0_.A by A12,POLYNOM4:12;
	hence Ext_eval(Leading-Monomial(p),x) =
	0.B*(power B).(x,len p-'1) by Th17
	.= In(0.A,B) *(power B).(x,len p-'1) by A0,Lm5
	.= In(p.(len p-'1),B)*(power B).(x,len p-'1) by A13,FUNCOP_1:7;
	end;
	end;

	::Modify POLYNOM_4:Lm3:
	theorem Th22:
	for B be comRing
	for p,q be Polynomial of A for x be Element of B st A is Subring of B holds
	Ext_eval( (Leading-Monomial p)*'(Leading-Monomial q),x) =
	Ext_eval(Leading-Monomial(p),x)*Ext_eval(Leading-Monomial(q),x)
	proof
	let B be comRing;
	let p,q be Polynomial of A;
	let x be Element of B;
	assume
	A0: A is Subring of B;
	per cases;
	suppose
	A1: len p <> 0 & len q <> 0; then
	A2: len q >= 0+1 & len p >= 0+1 by NAT_1:13;
	A3: len q-1 = len q-'1 & len p-1 = len p-'1 by A1,XREAL_0:def 2;
	len p+len q >= 0+(1+1) by A2,XREAL_1:7; then
	A4: len p+len q-'2 = len p+len q-2 by XREAL_1:19,XREAL_0:def 2;
	A5: len p+len q-(1+1) = len p-1+(len q-1);
	thus
	Ext_eval((Leading-Monomial(p))*'(Leading-Monomial(q)),x) =
	In(p.(len p-'1)*q.(len q-'1),B)
	*(power B).(x,len p+len q-'2) by A0,A1,Th20
	.= In(p.(len p-'1)*q.(len q-'1),B)
	((power B).(x,len p-'1)(power B).(x,len q-'1)) by A3,A4,A5,POLYNOM2:1
	.= In(p.(len p-'1),B)In(q.(len q-'1),B)
	((power B).(x,len p-'1)*(power B).(x,len q-'1)) by A0,Th13
	.= In(p.(len p-'1),B)(In(q.(len q-'1),B)
	((power B).(x,len p-'1)*(power B).(x,len q-'1))) by GROUP_1:def 3
	.= In(p.(len p-'1),B)((power B).(x,len p-'1)
	(In(q.(len q-'1),B)*(power B).(x,len q-'1)))
	by GROUP_1:def 3
	.= In(p.(len p-'1),B)(power B).(x,len p-'1)
	(In(q.(len q-'1),B)*(power B).(x,len q-'1)) by GROUP_1:def 3
	.= In(p.(len p-'1),B)(power B).(x,len p-'1)
	Ext_eval(Leading-Monomial(q),x) by A0,Th21
	.= Ext_eval(Leading-Monomial(p),x)*Ext_eval(Leading-Monomial(q),x)
	by A0,Th21;
	end;
	suppose
	len p = 0; then
	A6: Leading-Monomial(p) = 0_.A by POLYNOM4:12;
	hence Ext_eval((Leading-Monomial(p))*'(Leading-Monomial(q)),x) =
	Ext_eval(0_.A,x) by POLYNOM4:2
	.= 0.B * Ext_eval(Leading-Monomial(q),x) by Th17
	.= Ext_eval(Leading-Monomial(p),x)* Ext_eval(Leading-Monomial(q),x)
	by A6,Th17;
	end;
	suppose
	len q = 0;
	then len Leading-Monomial(q) = 0 by POLYNOM4:15; then
	A7: Leading-Monomial(q) = 0_.A by POLYNOM4:5;
	hence Ext_eval((Leading-Monomial(p))*'(Leading-Monomial(q)),x)
	= Ext_eval(0_.A,x) by POLYNOM3:34
	.= Ext_eval(Leading-Monomial(p),x)*0.B by Th17
	.= Ext_eval(Leading-Monomial(p),x)* Ext_eval(Leading-Monomial(q),x)
	by A7,Th17;
	end;
	end;

	:: Modify POLYNOM4:23
	theorem Th15:
	for B be comRing
	for p,q be Polynomial of A for x be Element of B st A is Subring of B holds
	Ext_eval((Leading-Monomial p)*'q,x)
	= Ext_eval(Leading-Monomial(p),x) * Ext_eval(q,x)
	proof
	let B be comRing;
	let p1,q be Polynomial of A;
	let x be Element of B;
	assume
	A0: A is Subring of B;
	set p=Leading-Monomial(p1);
	defpred P[Nat] means for q be Polynomial of A holds len q = $1 implies
	Ext_eval(p'q,x) = Ext_eval(p,x)Ext_eval(q,x);
	A1: for k be Nat st for n be Nat st n < k holds P[n] holds P[k]
	proof
	let k be Nat;
	assume
	A2: for n be Nat st n < k holds for q be Polynomial of A holds len q = n
	implies Ext_eval(p'q,x) = Ext_eval(p,x) Ext_eval(q,x);
	let q be Polynomial of A;
	assume
	A3: len q = k;
	per cases;
	suppose
	A4: len q <> 0;
	set LMq = Leading-Monomial(q);
	consider r be Polynomial of A such that
	A5: len r < len q and
	A6: q = r+Leading-Monomial(q) and
	for n be Element of NAT st n < len q-1 holds r.n = q.n
	by A4,POLYNOM4:16;
	thus Ext_eval(p'q,x)=Ext_eval(p'r+p*'LMq,x) by A6,POLYNOM3:31
	.= Ext_eval(p'r,x) + Ext_eval(p'LMq,x) by A0,Th19
	.= Ext_eval(p,x)Ext_eval(r,x)+Ext_eval(p'LMq,x) by A2,A3,A5
	.= Ext_eval(p,x)Ext_eval(r,x) + Ext_eval(p,x)Ext_eval(LMq,x)
	by A0,Th22
	.= Ext_eval(p,x)*(Ext_eval(r,x) + Ext_eval(LMq,x))
	by VECTSP_1:def 7
	.= Ext_eval(p,x) * Ext_eval(q,x) by A0,A6,Th19;
	end;
	suppose
	len q = 0; then
	A7: q = 0_.A by POLYNOM4:5;
	hence Ext_eval(p*'q,x) = Ext_eval(0_.A,x) by POLYNOM3:34
	.= Ext_eval(p,x) * 0.B by Th17
	.= Ext_eval(p,x) * Ext_eval(q,x) by A7,Th17;
	end;
	end;
	A8: for n be Nat holds P[n] from NAT_1:sch 4(A1);
	len q = len q;
	hence thesis by A8;
	end;

	:: Modify POLYNOM4:24
	theorem Th24:
	for B be comRing
	for p,q be Polynomial of A for x be Element of B st A is Subring of B
	holds Ext_eval(p'q,x) = Ext_eval(p,x) Ext_eval(q,x)
	proof
	let B be comRing;
	let p,q be Polynomial of A;
	let x be Element of B;
	assume
	A0: A is Subring of B;
	defpred P[Nat] means for p be Polynomial of A holds len p = $1
	implies Ext_eval(p'q,x) = Ext_eval(p,x) Ext_eval(q,x);
	A1: for k be Nat st for n be Nat st n < k holds P[n] holds P[k]
	proof
	let k be Nat;
	assume
	A2: for n be Nat st n < k holds for p be Polynomial of A holds len p =
	n implies Ext_eval(p'q,x) = Ext_eval(p,x) Ext_eval(q,x);
	let p be Polynomial of A;
	assume
	A3: len p = k;
	per cases;
	suppose
	A4: len p <> 0;
	set LMp = Leading-Monomial(p);
	consider r be Polynomial of A such that
	A5: len r < len p and
	A6: p = r+Leading-Monomial(p) and
	for n be Element of NAT st n < len p-1 holds r.n = p.n by A4,POLYNOM4:16;
	thus Ext_eval(p'q,x) = Ext_eval(r'q+LMp*'q,x) by A6,POLYNOM3:32
	.= Ext_eval(r'q,x) + Ext_eval(LMp'q,x) by A0,Th19
	.= Ext_eval(r,x)Ext_eval(q,x) + Ext_eval(LMp'q,x) by A2,A3,A5
	.= Ext_eval(r,x)Ext_eval(q,x) + Ext_eval(LMp,x)Ext_eval(q,x)
	by A0,Th15
	.= (Ext_eval(r,x)+Ext_eval(LMp,x))*Ext_eval(q,x) by VECTSP_1:def 7
	.= Ext_eval(p,x) * Ext_eval(q,x) by A0,A6,Th19;
	end;
	suppose
	len p = 0; then
	A7: p = 0_.A by POLYNOM4:5;
	hence Ext_eval(p*'q,x) = Ext_eval(0_.A,x) by POLYNOM4:2
	.= 0.B * Ext_eval(q,x) by Th17
	.= Ext_eval(p,x) * Ext_eval(q,x) by A7,Th17;
	end;
	end;
	A8: for n be Nat holds P[n] from NAT_1:sch 4(A1);
	len p = len p;
	hence thesis by A8;
	end;

	:: modified POLYNOM5:37
	theorem Th25:
	for x be Element of B, z0 be Element of A
	st A is Subring of B holds Ext_eval(<%z0%>,x) = In(z0,B)
	proof
	let x be Element of B, z0 be Element of A;
	assume
	A0: A is Subring of B;
	consider F be FinSequence of B such that
	A1: Ext_eval(<%z0%>,x) = Sum F and
	A2: len F = len <%z0%> and
	A3: for n be Element of NAT st n in dom F holds
	F.n = In(<%z0%>.(n-'1),B)*(power B).(x,n-'1) by Def1;
	per cases by A2,ALGSEQ_1:def 5,NAT_1:25;
	suppose
	A4: len F = 0;
	A5: z0 = <%z0%>.0 by POLYNOM5:32 .= (0_.A).0 by A4,A2,POLYNOM4:5
	.=0.A by FUNCOP_1:7;
	Ext_eval(<%z0%>,x) = Ext_eval(0_.A,x) by A4,A2,POLYNOM4:5
	.= 0.B by Th17
	.= In(z0,B) by A5,A0,Lm5;
	hence thesis;
	end;
	suppose
	A6: len F = 1; then
	A7: F.1 = In(<%z0%>.(1-'1),B)*(power B).(x,1-'1) by A3,FINSEQ_3:25
	.=In( <%z0%>.0,B)*(power B).(x,1-'1) by XREAL_1:232
	.= In( <%z0%>.0,B)*(power B).(x,0) by XREAL_1:232
	.= In( z0,B) * (power B).(x,0) by POLYNOM5:32
	.= In(z0,B) * 1_B by GROUP_1:def 7
	.= In(z0,B);
	Ext_eval(<%z0%>,x) = Sum <In(z0,B)> by A6,A7,FINSEQ_1:40,A1
	.= In(z0,B) by RLVECT_1:44;
	hence thesis;
	end;
	end;

	:: modified POLYNOM5:44
	theorem
	for x be Element of B, z0,z1 be Element of A st A is Subring of B
	holds Ext_eval(<%z0,z1%>,x) = In(z0,B)+In(z1,B)*x
	proof
	let x be Element of B, z0,z1 be Element of A;
	assume
	A0: A is Subring of B;
	consider F be FinSequence of B such that
	A1: Ext_eval(<%z0,z1%>,x) = Sum F and
	A2: len F = len <%z0,z1%> and
	A3: for n be Element of NAT st n in dom F holds
	F.n = In(<%z0,z1%>.(n-'1),B)*(power B).(x,n-'1) by Def1;
	len F = 0 or ... or len F = 2 by A2,POLYNOM5:39;
	then per cases;
	suppose
	len F = 0; then
	A4: <%z0,z1%> = 0_.A by A2,POLYNOM4:5;
	hence Ext_eval(<%z0,z1%>,x)=0.B by Th17.=In(0.A,B) by A0,Lm5
	.= In((0_.A).0,B) by FUNCOP_1:7
	.= In(z0,B)+ 0.B * x by A4,POLYNOM5:38
	.= In(z0,B) + In(0.A,B) *x by A0,Lm5
	.= In(z0,B) + In((0_.A).1,B)*x by FUNCOP_1:7
	.= In(z0,B)+ In(z1,B)*x by A4,POLYNOM5:38;
	end;
	suppose
	A5: len F = 1;
	then F.1 = In(<%z0,z1%>.(1-'1),B)*(power B).(x,1-'1) by A3,FINSEQ_3:25
	.= In(<%z0,z1%>.0,B)* (power B).(x,1-'1) by XREAL_1:232
	.= In(<%z0,z1%>.0,B)* (power B).(x,0) by XREAL_1:232
	.= In(z0,B) * (power B).(x,0) by POLYNOM5:38
	.= In(z0,B) * 1_B by GROUP_1:def 7
	.= In(z0,B);
	then F = <In(z0,B)> by A5,FINSEQ_1:40;
	hence Ext_eval(<%z0,z1%>,x) = In(z0,B) + 0.B*x by A1,RLVECT_1:44
	.= In(z0,B) + In(0.A,B) *x by A0,Lm5
	.= In(z0,B) + In(<%z0,z1%>.1,B)*x by A2,A5,ALGSEQ_1:8
	.= In(z0,B) + In(z1,B)*x by POLYNOM5:38;
	end;
	suppose
	A6: len F = 2; then
	A7: F.1 = In(<%z0,z1%>.(1-'1),B)*(power B).(x,1-'1) by A3,FINSEQ_3:25
	.= In(<%z0,z1%>.0,B)* (power B).(x,1-'1) by XREAL_1:232
	.= In(<%z0,z1%>.0,B)* (power B).(x,0) by XREAL_1:232
	.= In(z0,B) * (power B).(x,0) by POLYNOM5:38
	.= In(z0,B) * 1_B by GROUP_1:def 7
	.= In(z0,B);
	A8: 2-'1 = 2-1 by XREAL_0:def 2;
	F.2 = In(<%z0,z1%>.(2-'1),B)*(power B).(x,2-'1) by A3,A6,FINSEQ_3:25
	.= In(z1,B) * (power B).(x,1) by A8,POLYNOM5:38
	.= In(z1,B) * x by GROUP_1:50;
	then F = <* In(z0,B),In(z1,B)x > by A6,A7,FINSEQ_1:44;
	hence thesis by A1,RLVECT_1:45;
	end;
	end;

	begin
	:: Definition of Integral Element over A in B

	definition
	let A,B be Ring;
	let x be Element of B;
	pred x is_integral_over A means
	ex f be Polynomial of A st LC f = 1.A & Ext_eval(f,x) = 0.B;
	end;

	theorem Th27:
	for A being non degenerated Ring
	for a be Element of A st A is Subring of B holds
	In(a,B) is_integral_over A
	proof
	let A be non degenerated Ring;
	let a be Element of A;
	assume
	A0: A is Subring of B;
	set p = <% -a, 1.A %>;
	p.(len p -' 1) = p.(2-'1) by POLYNOM5:40 .= p.(2-1) by XREAL_1:233
	.= p.1; then
	A2: LC p = 1.A by POLYNOM5:38;
	A3: eval(p,a) = -a + a by POLYNOM5:47
	.= a - a .= 0.A by RLVECT_1:15;
	Ext_eval(p,In(a,B)) = In(eval(p,a),B) by A0,Th16
	.= 0.B by A0,Lm5,A3;
	hence thesis by A2;
	end;

	definition
	let A be non degenerated Ring, B be Ring;
	assume
	A0: A is Subring of B;
	func integral_closure(A,B) -> non empty Subset of B equals
	{z where z is Element of B: z is_integral_over A};
	coherence
	proof
	set M ={z where z is Element of B: z is_integral_over A};
	A1: now
	let u be object;
	assume u in M;
	then ex z being Element of B st u = z & z is_integral_over A;
	hence u in the carrier of B;
	end;
	In(0.A,B) is_integral_over A by A0,Th27; then
	0.B is_integral_over A by A0,Lm5; then
	0.B in M;
	hence thesis by A1,TARSKI:def 3;
	end;
	end;

	definition
	let c be Complex;
	attr c is algebraic means
	ex x being Element of F_Complex st x = c & x is_integral_over F_Rat;
	end;

	definition
	let x be Element of F_Complex;
	redefine attr x is algebraic means
	x is_integral_over F_Rat;
	compatibility;
	end;

	definition
	let c be Complex;
	attr c is algebraic_integer means
	ex x being Element of F_Complex st x = c & x is_integral_over INT.Ring;
	end;

	definition
	let x be Element of F_Complex;
	redefine attr x is algebraic_integer means
	x is_integral_over INT.Ring;
	compatibility;
	end;

	notation
	let x be Complex;
	antonym x is transcendental for x is algebraic;
	end;

	registration
	cluster rational -> algebraic for Complex;
	coherence
	proof
	let c be Complex;
	assume c is rational;
	then reconsider c as Element of F_Rat by RAT_1:def 2;
	take In(c,F_Complex);
	thus thesis by Th3,Th27;
	end;
	end;

	registration
	cluster algebraic for Complex;
	existence by GAUSSINT:14;
	cluster algebraic for Element of F_Complex;
	existence by Lm7;
	end;

	registration
	cluster integer -> algebraic_integer for Complex;
	coherence
	proof
	let c be Complex;
	assume c is integer;
	then reconsider c as Element of INT.Ring by INT_1:def 2;
	take In(c,F_Complex);
	thus thesis by Th4,Th27;
	end;
	end;

	registration
	cluster algebraic_integer for Complex;
	existence by GAUSSINT:14;
	cluster algebraic_integer for Element of F_Complex;
	existence by Lm7;
	end;

	definition
	let A,B be Ring;
	let x be Element of B;
	func Ann_Poly(x,A) -> non empty Subset of Polynom-Ring A equals
	{p where p is Polynomial of A: Ext_eval(p,x) = 0.B};
	coherence
	proof
	set M ={p where p is Polynomial of A:Ext_eval(p,x) = 0.B};
	A1: now
	let u be object;
	assume u in M; then
	ex p1 being Polynomial of A st u = p1 & Ext_eval(p1,x)=0.B;
	hence u in the carrier of Polynom-Ring A by POLYNOM3:def 10;
	end;
	Ext_eval(0_.A,x) = 0.B by Th17; then
	0_.A in M;
	hence thesis by A1,TARSKI:def 3;
	end;
	end;

	theorem Lm30:
	for A,B be Ring, w be Element of B, x, y being Element of Polynom-Ring A
	st A is Subring of B & x in Ann_Poly(w,A) & y in Ann_Poly(w,A)
	holds x + y in Ann_Poly(w,A)
	proof
	let A,B;
	let w be Element of B;
	let x,y be Element of Polynom-Ring A;
	assume that
	A0: A is Subring of B and
	A1: x in Ann_Poly(w,A) and
	A2: y in Ann_Poly(w,A);
	reconsider x1=x, y1=y as Polynomial of A by POLYNOM3:def 10;
	set M ={p where p is Polynomial of A:Ext_eval(p,w)=0.B};
	consider x2 be Polynomial of A such that
	A3: x2 = x1 and
	A4: Ext_eval(x2,w)=0.B by A1;
	consider y2 be Polynomial of A such that
	A5: y2 = y1 and
	A6: Ext_eval(y2,w)=0.B by A2;
	A7: Ext_eval(x2 + y2,w) = Ext_eval(x1,w) + 0.B by A0,Th19,A6,A3
	.= 0.B by A3,A4;
	consider t be Polynomial of A such that
	A8: t = x1+y1 and
	A9: Ext_eval(t,w) = 0.B by A3,A5,A7;
	x1+ y1 in M by A8,A9;
	hence thesis by POLYNOM3:def 10;
	end;

	theorem Th31:
	for B be comRing, z be Element of B, p, x being Element of Polynom-Ring A
	st A is Subring of B & x in Ann_Poly(z,A) holds p * x in Ann_Poly(z,A)
	proof
	let B be comRing;
	let w be Element of B;
	let p,x be Element of Polynom-Ring A;
	assume that
	A0: A is Subring of B and
	A1: x in Ann_Poly(w,A);
	set M ={p where p is Polynomial of A:Ext_eval(p,w)=0.B};
	reconsider p1=p, x1=x as Polynomial of A by POLYNOM3:def 10;
	consider x2 be Polynomial of A such that
	A2: x2 = x1 and
	A3: Ext_eval(x2,w)=0.B by A1;
	Ext_eval(p1 'x1,w) = Ext_eval(p1,w) 0.B by A0,A2,A3,Th24.= 0.B;
	then
	consider t be Polynomial of A such that
	A4: t = p1 *'x1 and
	A5: Ext_eval(t,w) = 0.B;
	p1 *'x1 in M by A4,A5;
	hence thesis by POLYNOM3:def 10;
	end;

	theorem Lm32:
	for B be comRing
	for w be Element of B, p, x being Element of Polynom-Ring A
	st A is Subring of B & x in Ann_Poly(w,A) holds x * p in Ann_Poly(w,A)
	proof
	let B be comRing;
	let w be Element of B;
	let p,x be Element of Polynom-Ring A;
	set M ={p where p is Polynomial of A:Ext_eval(p,w)=0.B};
	reconsider p1=p, x1=x as Polynomial of A by POLYNOM3:def 10;
	assume that
	A0: A is Subring of B and
	A1: x in Ann_Poly(w,A);
	consider x2 be Polynomial of A such that
	A2: x2 = x1 and
	A3: Ext_eval(x2,w)=0.B by A1;
	Ext_eval(x1'p1,w) = Ext_eval(p1,w) 0.B by A0,A2,A3,Th24
	.= 0.B; then
	consider t be Polynomial of A such that
	A4: t = x1 *'p1 and
	A5: Ext_eval(t,w) = 0.B;
	x1 *'p1 in M by A4,A5;
	hence thesis by POLYNOM3:def 10;
	end;

	theorem Th33:
	for A be non degenerated Ring
	for B be non degenerated comRing
	for w be Element of B st A is Subring of B
	holds Ann_Poly(w,A) is proper Ideal of Polynom-Ring A
	proof
	let A be non degenerated Ring;
	let B be non degenerated comRing;
	let w be Element of B;
	assume
	A0: A is Subring of B;
	A1: Ann_Poly(w,A) is add-closed by A0,Lm30;
	A2: Ann_Poly(w,A) is left-ideal by A0,Th31;
	A3: Ann_Poly(w,A) is right-ideal by A0,Lm32;
	Ann_Poly(w,A) is proper
	proof
	assume not Ann_Poly(w,A) is proper; then
	A5: 1.Polynom-RingA in Ann_Poly(w,A);
	A6: 1_.A in Ann_Poly(w,A) by A5,POLYNOM3:37;
	A7: Ext_eval(1_.A,w)= 1.B by A0,Th18;
	ex p be Polynomial of A st p = 1_.A & Ext_eval(p,w)= 0.B by A6;
	hence contradiction by A7;
	end;
	hence thesis by A1,A2,A3;
	end;

	begin :: Properties of Polynomial Ring over PID.

	reserve K, L for Field;

	theorem Th34:
	for K,L be Field, w be Element of L st K is Subring of L holds
	ex g be Element of Polynom-Ring K st {g}-Ideal = Ann_Poly(w,K)
	proof
	let K,L;
	let w be Element of L;
	assume
	A0: K is Subring of L;
	A1: Polynom-Ring K is PID;
	Ann_Poly(w,K) is Ideal of Polynom-Ring K by A0,Th33;
	hence thesis by A1,IDEAL_1:def 27;
	end;

	theorem Th35:
	for K,L be Field, z be Element of L st z is_integral_over K
	holds Ann_Poly(z,K) <> {0.Polynom-Ring K}
	proof
	let K,L;
	let z be Element of L;
	assume
	A1: z is_integral_over K;
	set M = {p where p is Polynomial of K:Ext_eval(p,z)=0.L};
	consider f be Polynomial of K such that
	A2: LC f = 1.K and
	A3: Ext_eval(f,z) = 0.L by A1;
	not f in {0.Polynom-Ring K}
	proof
	assume
	A5: f in {0.Polynom-Ring K};
	reconsider f as Element of Polynom-Ring K by POLYNOM3:def 10;
	f in {0.Polynom-Ring K}-Ideal by A5,IDEAL_1:47; then
	f in the set of all 0.Polynom-Ring K*g
	where g is Element of Polynom-Ring K by IDEAL_1:64; then
	consider g1 being Element of Polynom-Ring K such that
	A6: f = 0.Polynom-Ring K * g1;
	reconsider g2 = g1 as Polynomial of K by POLYNOM3:def 10;
	reconsider h2 = 0.Polynom-Ring K as Polynomial of K by POLYNOM3:def 10;
	f = 0_.K by POLYNOM3:def 10,A6;
	hence contradiction by FUNCOP_1:7,A2;
	end;
	hence thesis by A3;
	end;

	theorem Lm37:
	for K be Field, p be Element of Polynom-Ring K st p <> 0_.K holds
	p is non zero Element of the carrier of Polynom-Ring K
	proof
	let K;
	let p be Element of Polynom-Ring K;
	assume
	A0: p <> 0_.K;
	assume
	A1: not(p is non zero Element of the carrier of Polynom-Ring K);
	reconsider p as Element of the carrier of Polynom-Ring K;
	p is zero by A1;
	hence contradiction by A0;
	end;

	theorem Th38:
	for K,L be Field, w be Element of L st K is Subring of L
	holds Ann_Poly(w,K) is quasi-prime
	proof
	let K,L;
	let w be Element of L;
	assume
	A0: K is Subring of L;
	set M = {p where p is Polynomial of K:Ext_eval(p,w)=0.L};
	for p, q being Element of Polynom-Ring K st p*q in Ann_Poly(w,K) holds
	p in Ann_Poly(w,K) or q in Ann_Poly(w,K)
	proof
	let p, q be Element of Polynom-Ring K;
	assume
	A1: p*q in Ann_Poly(w,K);
	reconsider p1=p, q1=q as Polynomial of K by POLYNOM3:def 10;
	p1*'q1 in Ann_Poly(w,K) by A1,POLYNOM3:def 10; then
	consider t be Polynomial of K such that
	A5: t = p1*'q1 and
	A6: Ext_eval(t,w)=0.L;
	Ext_eval(p1,w) * Ext_eval(q1,w) = 0.L by A0,Th24,A6,A5;
	then per cases by VECTSP_2:def 1;
	suppose Ext_eval(p1,w)=0.L;
	hence thesis;
	end;
	suppose Ext_eval(q1,w)=0.L;
	hence thesis;
	end;
	end;
	hence thesis by RING_1:def 1;
	end;

	theorem Th39:
	for K,L be Field, w be Element of L st K is Subring of L &
	w is_integral_over K holds Ann_Poly(w,K) is prime
	proof
	let K,L;
	let w be Element of L;
	assume K is Subring of L & w is_integral_over K;
	then Ann_Poly(w,K) is proper quasi-prime by Th38,Th33;
	hence thesis;
	end;

	theorem Th40:
	for K,L be Field, z be Element of L st K is Subring of L &
	z is_integral_over K
	ex f be Element of Polynom-Ring K
	st f <> 0_.K & {f}-Ideal = Ann_Poly(z,K) & f = NormPolynomial(f)
	proof
	let K,L be Field;
	let z be Element of L;
	assume that
	A0: K is Subring of L and
	A1: z is_integral_over K;
	consider f be Element of Polynom-Ring K such that
	A2: {f}-Ideal = Ann_Poly(z,K) by A0,Th34;
	A3: f <> 0.Polynom-Ring K by A1,A2,Th35,IDEAL_1:47;
	reconsider f as Element of Polynom-Ring K;
	A4: f <> 0_.K by A3,POLYNOM3:def 10;
	set g = NormPolynomial(f);
	A7: {g}-Ideal = Ann_Poly(z,K) by A2,RING_4:27,RING_2:21;
	g <> 0.Polynom-Ring K by A1,A7,Th35,IDEAL_1:47; then
	A8: g <> 0_.K by POLYNOM3:def 10; then
	A9: g is non zero Element of the carrier of Polynom-Ring K by Lm37;
	A10:f is non zero Element of the carrier of Polynom-Ring K by A4,Lm37;
	g = NormPolynomial(g) by A9,A10,RING_4:24;
	hence thesis by A7,A8;
	end;

	theorem Th41:
	for K,L be Field, z be Element of L,f,g be Element of Polynom-Ring K st
	z is_integral_over K &
	{f}-Ideal = Ann_Poly(z,K) & f = NormPolynomial(f) &
	{g}-Ideal = Ann_Poly(z,K) & g = NormPolynomial(g)
	holds f = g
	proof
	let K,L be Field;
	let z be Element of L;
	let f,g be Element of Polynom-Ring K;
	assume that
	A1: z is_integral_over K and
	A2: {f}-Ideal = Ann_Poly(z,K) and
	A3: f = NormPolynomial(f) and
	A4: {g}-Ideal = Ann_Poly(z,K) and
	A5: g = NormPolynomial(g);
	reconsider f as Element of the carrier of Polynom-Ring K;
	NormPolynomial(f) <> 0.(Polynom-Ring K) by A3,A2,A1,Th35,IDEAL_1:47; then
	f <> 0_.K by A3,POLYNOM3:def 10; then
	A6: f is non zero Element of the carrier of Polynom-Ring K by Lm37;
	reconsider g as Element of the carrier of Polynom-Ring K;
	NormPolynomial(g) <> 0.(Polynom-Ring K) by A5,A4,A1,Th35,IDEAL_1:47; then
	g <> 0_.K by A5,POLYNOM3:def 10; then
	g is non zero Element of the carrier of Polynom-Ring K by Lm37;
	hence thesis by A3,A6,A5,RING_2:21,RING_4:30,A4,A2;
	end;

	definition
	let K,L be Field;
	let z be Element of L;
	assume that
	A1: K is Subring of L and
	A2: z is_integral_over K;
	func minimal_polynom(z,K) -> Element of the carrier of Polynom-Ring K
	means
	:Def7:
	it <> 0_.K & {it}-Ideal = Ann_Poly(z,K) & it = NormPolynomial(it);
	existence by A1,A2,Th40;
	uniqueness by Th41,A2;
	end;

	definition
	let K,L be Field;
	let z be Element of L;
	assume that
	A1: K is Subring of L and
	A2: z is_integral_over K;
	func deg_of_integral_element(z,K) -> Element of NAT equals
	deg (minimal_polynom(z,K));
	coherence
	proof
	set f = minimal_polynom(z,K);
	A7: f is non zero by A1,A2,Def7;
	reconsider f as Polynomial of K;
	deg f <> -1 by A7; then
	A8: len f <> 0;
	len f + 1 > 0 + 1 by A8,XREAL_1:8; then
	len f >= 1 by NAT_1:13;
	hence thesis by INT_1:3;
	end;
	end;

	definition
	let A,B be Ring;
	let x be Element of B;
	func hom_Ext_eval(x,A) -> Function of Polynom-Ring A,B means :Def9:
	for p be Polynomial of A holds it.p = Ext_eval(p,x);
	existence
	proof
	defpred P[set,set] means ex p be Polynomial of A st p = $1 &
	$2 = Ext_eval(p,x);
	A1: for y be Element of the carrier of Polynom-Ring A
	ex z be Element of B st P[y,z]
	proof
	let y be Element of the carrier of Polynom-Ring A;
	reconsider p=y as Polynomial of A;
	take Ext_eval(p,x);
	take p;
	thus thesis;
	end;
	consider f be Function of Polynom-Ring A, B such that
	A2: for y be Element of Polynom-Ring A holds P[y,f.y]
	from FUNCT_2:sch 3 (A1);
	reconsider f as Function of Polynom-Ring A, B;
	take f;
	let p be Polynomial of A;
	p in Polynom-Ring A by POLYNOM3:def 10; then
	ex q be Polynomial of A st q = p & f.p = Ext_eval(q,x) by A2;
	hence thesis;
	end;
	uniqueness
	proof
	let f1,f2 be Function of Polynom-Ring A, B such that
	A3: for p be Polynomial of A holds f1.p = Ext_eval(p,x) and
	A4: for p be Polynomial of A holds f2.p = Ext_eval(p,x);
	now
	let y be Element of Polynom-Ring A;
	reconsider p=y as Polynomial of A by POLYNOM3:def 10;
	thus f1.y = Ext_eval(p,x) by A3 .= f2.y by A4;
	end;
	hence f1 = f2;
	end;
	end;

	registration
	let x be Element of F_Complex;
	cluster hom_Ext_eval(x,F_Rat) -> unity-preserving additive multiplicative;
	coherence
	proof
	thus (hom_Ext_eval(x,F_Rat)).(1_Polynom-Ring F_Rat)
	= (hom_Ext_eval(x,F_Rat)).(1_.(F_Rat)) by POLYNOM3:37
	.= Ext_eval(1_.(F_Rat),x) by Def9
	.= 1_F_Complex by Th3,Th18;
	hereby let a,b be Element of Polynom-Ring F_Rat;
	reconsider p=a,q=b as Polynomial of F_Rat by POLYNOM3:def 10;
	thus hom_Ext_eval(x,F_Rat).(a+b) = hom_Ext_eval(x,F_Rat).(p+q) by
	POLYNOM3:def 10
	.= Ext_eval(p+q,x) by Def9
	.= Ext_eval(p,x) + Ext_eval(q,x) by Th3,Th19
	.= hom_Ext_eval(x,F_Rat).a + Ext_eval(q,x) by Def9
	.= hom_Ext_eval(x,F_Rat).a + hom_Ext_eval(x,F_Rat).b by Def9;
	end;
	hereby let a,b be Element of Polynom-Ring F_Rat;
	reconsider p=a,q=b as Polynomial of F_Rat by POLYNOM3:def 10;
	thus (hom_Ext_eval(x,F_Rat)).(ab) = (hom_Ext_eval(x,F_Rat)).(p'q)
	by POLYNOM3:def 10
	.= Ext_eval(p*'q,x) by Def9
	.= Ext_eval(p,x)* Ext_eval(q,x) by Th3,Th24
	.= (hom_Ext_eval(x,F_Rat)).a*Ext_eval(q,x) by Def9
	.= (hom_Ext_eval(x,F_Rat)).a*(hom_Ext_eval(x,F_Rat)).b by Def9;
	end;
	end;
	end;

	theorem
	for x be Element of F_Complex holds
	F_Complex is (Polynom-Ring F_Rat)-homomorphic
	proof
	let x be Element of F_Complex;
	hom_Ext_eval(x,F_Rat) is RingHomomorphism;
	hence thesis;
	end;

	theorem Lm45:
	for x be Element of B, z be object st z in rng hom_Ext_eval(x,A)
	holds z in B;

	definition
	let x be Element of F_Complex;
	func FQ(x) -> Subset of F_Complex equals
	rng hom_Ext_eval(x,F_Rat);
	coherence;
	end;

	registration
	let x be Element of F_Complex;
	cluster FQ(x) -> non empty;
	coherence;
	end;

	theorem Lm46:
	for x,z1,z2 be Element of F_Complex st
	z1 in FQ(x) & z2 in FQ(x) holds z1 + z2 in FQ(x)
	proof
	let x,z1,z2 be Element of F_Complex;
	assume that
	A1: z1 in FQ(x) and
	A2: z2 in FQ(x);
	consider f1 be object such that
	A3: f1 in dom hom_Ext_eval(x,F_Rat) and
	A4: z1 = hom_Ext_eval(x,F_Rat).f1 by A1,FUNCT_1:def 3;
	consider f2 be object such that
	A5: f2 in dom hom_Ext_eval(x,F_Rat) and
	A6: z2 = hom_Ext_eval(x,F_Rat).f2 by A2,FUNCT_1:def 3;
	A7: dom hom_Ext_eval(x,F_Rat) =
	the carrier of Polynom-Ring F_Rat by FUNCT_2:def 1;
	reconsider g1 = f1, g2 = f2 as Polynomial of F_Rat
	by A3,A5,POLYNOM3:def 10;
	A8: z1 + z2 = Ext_eval(g1,x) + hom_Ext_eval(x,F_Rat).f2 by Def9,A6,A4
	.= Ext_eval(g1,x) + Ext_eval(g2,x) by Def9
	.= Ext_eval(g1+g2,x) by Th3,Th19
	.= hom_Ext_eval(x,F_Rat).(g1+g2) by Def9;
	set g = g1+g2;
	g in dom hom_Ext_eval(x,F_Rat) by A7,POLYNOM3:def 10;
	hence thesis by A8,FUNCT_1:def 3;
	end;

	theorem Lm47:
	for x,z1,z2 be Element of F_Complex st
	z1 in FQ(x) & z2 in FQ(x) holds z1 * z2 in FQ(x)
	proof
	let x,z1,z2 be Element of F_Complex;
	assume that
	A1: z1 in FQ(x) and
	A2: z2 in FQ(x);
	consider f1 be object such that
	A3: f1 in dom hom_Ext_eval(x,F_Rat) and
	A4: z1 = hom_Ext_eval(x,F_Rat).f1 by A1,FUNCT_1:def 3;
	consider f2 be object such that
	A5: f2 in dom hom_Ext_eval(x,F_Rat) and
	A6: z2 = hom_Ext_eval(x,F_Rat).f2 by A2,FUNCT_1:def 3;
	A7: dom hom_Ext_eval(x,F_Rat) =
	the carrier of Polynom-Ring F_Rat by FUNCT_2:def 1;
	reconsider g1 = f1, g2 = f2 as Polynomial of F_Rat by A3,A5,POLYNOM3:def 10;
	A8: z1 * z2 = Ext_eval(g1,x) * hom_Ext_eval(x,F_Rat).f2 by Def9,A6,A4
	.= Ext_eval(g1,x) * Ext_eval(g2,x) by Def9
	.= Ext_eval(g1*'g2,x) by Th3,Th24
	.= hom_Ext_eval(x,F_Rat).(g1*'g2) by Def9;
	set g = g1*'g2;
	g in dom hom_Ext_eval(x,F_Rat) by A7,POLYNOM3:def 10;
	hence thesis by A8,FUNCT_1:def 3;
	end;

	theorem Lm48:
	for x be Element of F_Complex, a be Element of F_Rat holds
	a in FQ(x)
	proof
	let x be Element of F_Complex;
	let a be Element of F_Rat;
	reconsider f = <% a %> as Polynomial of F_Rat;
	A2: dom hom_Ext_eval(x,F_Rat) =
	the carrier of Polynom-Ring F_Rat by FUNCT_2:def 1;
	A3: Ext_eval(f,x) = In(a,F_Complex) by Th3,Th25;
	reconsider f as Element of Polynom-Ring F_Rat by POLYNOM3:def 10;
	In(a,F_Complex) = hom_Ext_eval(x,F_Rat).f by A3,Def9;
	hence thesis by A2,FUNCT_1:def 3;
	end;

	definition
	let x be Element of F_Complex;
	func FQ_add(x) -> BinOp of FQ(x) equals
	addcomplex \|\| FQ(x);
	correctness
	proof
	set ad = addcomplex\|\|FQ(x);
	set theCFComplex = the carrier of F_Complex;
	A0: [:FQ(x),FQ(x):] c= [:theCFComplex,theCFComplex:];
	theCFComplex = COMPLEX by COMPLFLD:def 1; then
	[:FQ(x),FQ(x):] c= dom (addcomplex) by A0,FUNCT_2:def 1; then
	A1: dom ad = [:FQ(x),FQ(x):] by RELAT_1:62;
	for z be object st z in [:FQ(x),FQ(x):] holds ad. z in FQ(x)
	proof
	let z be object such that
	A2: z in [:FQ(x),FQ(x):];
	consider a, b be object such that
	A3: a in FQ(x) and
	A4: b in FQ(x) and
	A5: z = [a,b] by A2,ZFMISC_1:def 2;
	reconsider x1 = a, y1 = b as Element of theCFComplex by A3,A4;
	ad.z = addcomplex.(a,b) by A2,A5,FUNCT_1:49
	.= x1+y1 by BINOP_2:def 3;
	hence ad.z in FQ(x) by A3,A4,Lm46;
	end;
	hence thesis by A1,FUNCT_2:3;
	end;
	end;

	definition
	let x be Element of F_Complex;
	func FQ_mult(x) -> BinOp of FQ(x) equals
	multcomplex \|\| FQ(x);
	correctness
	proof
	set mult = multcomplex\|\|FQ(x);
	set theCFComplex = the carrier of F_Complex;
	A0: theCFComplex = COMPLEX by COMPLFLD:def 1;
	[:FQ(x),FQ(x):] c= [:COMPLEX,COMPLEX:] by A0; then
	[:FQ(x),FQ(x):] c= dom(multcomplex) by FUNCT_2:def 1; then
	A1: dom mult = [:FQ(x),FQ(x):] by RELAT_1:62;
	for z be object st z in [:FQ(x),FQ(x):] holds mult.z in FQ(x)
	proof
	let z be object such that
	A2: z in [:FQ(x),FQ(x):];
	consider x1,y1 be object such that
	A3: x1 in FQ(x) & y1 in FQ(x) & z = [x1,y1] by A2,ZFMISC_1:def 2;
	reconsider x2 = x1, y2 = y1 as Element of theCFComplex by A3;
	mult.z = multcomplex.(x2,y2) by A2,A3,FUNCT_1:49
	.= x2*y2 by BINOP_2:def 5;
	hence mult.z in FQ(x) by A3,Lm47;
	end;
	hence thesis by A1,FUNCT_2:3;
	end;
	end;

	theorem Th49:
	for x be Element of F_Complex, z, w be Element of FQ(x) holds
	(FQ_add(x)).(z,w) = z+w
	proof
	let x be Element of F_Complex;
	let z, w be Element of FQ(x);
	thus (FQ_add(x)).(z,w) = addcomplex.(z,w) by FUNCT_1:49,ZFMISC_1:87
	.= z+w by BINOP_2:def 3;
	end;

	theorem Th50:
	for x be Element of F_Complex, z, w be Element of FQ(x) holds
	(FQ_mult(x)).(z,w) = z*w
	proof
	let x be Element of F_Complex;
	let z, w be Element of FQ(x);
	thus (FQ_mult(x)).(z,w) = multcomplex.(z,w) by FUNCT_1:49,ZFMISC_1:87
	.= z*w by BINOP_2:def 5;
	end;

	theorem Lm52: :::?????
	for x be Element of F_Complex holds
	In(1.F_Complex, FQ(x)) = 1.F_Complex
	proof
	let x be Element of F_Complex;
	1.F_Complex = 1.F_Rat by C0SP1:def 3,Th3;
	hence thesis by Lm48,SUBSET_1:def 8;
	end;

	theorem Lm53:
	In(-1.F_Rat,F_Complex) = -1.F_Complex
	proof
	1.F_Complex + In(-1.F_Rat,F_Complex)
	= In(1.F_Rat,F_Complex) + In(-1.F_Rat,F_Complex) by Lm5,Th3
	.= In(0.F_Rat,F_Complex)
	.= 0.F_Complex by Lm5,Th3;
	hence thesis by RLVECT_1:def 10;
	end;

	definition
	let x be Element of F_Complex;
	func FQ_Ring(x) -> strict non empty doubleLoopStr equals
	doubleLoopStr(# FQ(x), FQ_add(x), FQ_mult(x),In(1.F_Complex,FQ(x)),
	In(0.F_Complex,FQ(x)) #);
	coherence;
	end;

	theorem Th54:
	for x be Element of F_Complex holds FQ_Ring(x) is Ring
	proof
	let x be Element of F_Complex;
	reconsider ZS = doubleLoopStr(# FQ(x),FQ_add(x),FQ_mult(x),
	In(1.F_Complex,FQ(x)),In(0.F_Complex,FQ(x)) #) as non empty doubleLoopStr;
	A1:for v, w being Element of ZS holds v + w = w + v
	proof
	let v, w be Element of ZS;
	v in F_Complex & w in F_Complex by Lm45; then
	reconsider v1 = v, w1 = w as Element of F_Complex;
	thus v + w = w1 + v1 by Th49
	.= w + v by Th49;
	end;
	A2: for u, v, w being Element of ZS holds (u + v) + w = u + (v + w)
	proof
	let u, v, w be Element of ZS;
	u in F_Complex & v in F_Complex & w in F_Complex by Lm45; then
	reconsider u1 = u, v1 = v, w1 = w as Element of F_Complex;
	A3: u + v = u1+v1 by Th49;
	A4: v + w = v1+w1 by Th49;
	thus (u + v) + w = u1+v1+w1 by Th49,A3
	.= u1+(v1+w1)
	.= u+(v+w) by Th49,A4;
	end;
	A5: for v being Element of ZS holds v + 0.ZS = v
	proof
	let v be Element of ZS;
	A6: 0.ZS = 0.F_Complex by Lm48,Lm7,SUBSET_1:def 8;
	0.ZS in F_Complex & v in F_Complex by Lm45; then
	reconsider v1 = v as Element of F_Complex;
	thus v + 0.ZS = v1 + 0.F_Complex by Th49,A6 .= v;
	end;
	A7: for v being Element of ZS holds v is right_complementable
	proof
	let v be Element of ZS;
	v in F_Complex by Lm45; then
	reconsider v1 = v as Element of F_Complex;
	A8: (-1.F_Complex) * v1 = -(1.F_Complex * v1) by VECTSP_1:9
	.= -v1;
	reconsider w1 = -1.F_Complex as Element of ZS by Lm48,Lm53;
	A10: w1 * v = (-1.F_Complex ) * v1 by Th50;
	take w1*v;
	thus v + (w1v) = v1 + ((-1.F_Complex ) v1) by A10,Th49
	.= 0.F_Complex by RLVECT_1:5,A8 .= 0.ZS by Lm48,Lm7,SUBSET_1:def 8;
	end;
	A11: for a, b, v being Element of ZS holds (a + b) * v = a * v + b * v
	proof
	let a, b, v be Element of ZS;
	a in F_Complex & b in F_Complex & v in F_Complex by Lm45; then
	reconsider a1 = a, b1 = b, v1 = v as Element of F_Complex;
	A12: a+b in FQ(x);
	reconsider ab = a+b as Element of F_Complex by A12;
	A13: a1v1 = av & (b1v1 = bv) by Th50;
	thus (a + b) * v = ab * v1 by Th50
	.= (a1 + b1) * v1 by Th49
	.= a1v1 + b1v1
	.= av + bv by A13,Th49;
	end;
	A14: for a, v, w being Element of ZS
	holds a * (v + w) = a * v + a * w & (v + w)a = va + w*a
	proof
	let a, v, w be Element of ZS;
	a in F_Complex & v in F_Complex & w in F_Complex by Lm45; then
	reconsider a1 = a, v1 = v, w1 = w as Element of F_Complex;
	A15: v+w in FQ(x);
	reconsider vw = (v+w) as Element of F_Complex by A15;
	A16: (a1v1 = av) & (a1w1 = aw) by Th50;
	thus a * (v + w) = a1 * vw by Th50
	.= a1 * (v1 + w1) by Th49
	.= a1v1 + a1w1
	.= av + aw by A16,Th49;
	thus (v + w) * a = va + wa by A11;
	end;
	A17: for a, b, v being Element of ZS holds (a * b) * v = a * (b * v)
	proof
	let a, b, v be Element of ZS;
	a in F_Complex & b in F_Complex & v in F_Complex by Lm45; then
	reconsider a1 = a, b1 = b, v1 = v as Element of F_Complex;
	A18: ab in FQ(x) & bv in FQ(x);
	reconsider ab = (ab), bv = (bv) as Element of F_Complex by A18;
	thus (a * b) * v = ab * v1 by Th50
	.= (a1 * b1) * v1 by Th50
	.= a1 * (b1 * v1)
	.= a1 * bv by Th50
	.= a * (b * v) by Th50;
	end;
	for v being Element of ZS holds v 1.ZS = v & 1.ZS v = v
	proof
	let v be Element of ZS;
	A19: 1.ZS = 1.F_Complex by Lm52;
	v in F_Complex by Lm45; then
	reconsider v1 = v as Element of F_Complex;
	thus v * 1.ZS = v1 * 1.F_Complex by A19,Th50
	.= v;
	thus 1.ZS * v = 1.F_Complex * v1 by A19,Th50
	.= v;
	end;
	hence thesis by A1,A2,A5,A7,A14,A17,VECTSP_1:def 6,def 7,
	GROUP_1:def 3,RLVECT_1:def 2,def 3,def 4,ALGSTR_0:def 16;
	end;

	registration
	let x be Element of F_Complex;
	cluster FQ_Ring(x) -> Abelian add-associative right_zeroed
	right_complementable associative well-unital distributive;
	coherence by Th54;
	end;

	registration
	let z be Element of F_Complex;
	cluster FQ_Ring(z) -> domRing-like commutative non degenerated;
	coherence
	proof
	set X = FQ_Ring(z);
	thus X is domRing-like
	proof
	for x, y being Element of X holds
	x*y = 0.X implies x = 0.X or y = 0.X
	proof
	let x, y be Element of X;
	x in F_Complex & y in F_Complex by Lm45; then
	reconsider x1 = x, y1 = y as Element of F_Complex;
	assume
	A1: x*y = 0.X;
	A2: 0.X = 0.F_Complex by Lm48,Lm7,SUBSET_1:def 8; then
	x1*y1 = 0.F_Complex by A1,Th50;
	hence thesis by A2,VECTSP_1:12;
	end;
	hence thesis by VECTSP_2:def 1;
	end;
	A3: 0.FQ_Ring(z) = 0.F_Complex by Lm48,Lm7,SUBSET_1:def 8;
	thus X is commutative
	proof
	let v, w be Element of FQ_Ring(z);
	v in F_Complex & w in F_Complex by Lm45; then
	reconsider v1=v, w1=w as Element of F_Complex;
	thus v * w = v1 * w1 by Th50
	.= w * v by Th50;
	end;
	thus thesis by Lm52,A3;
	end;
	end;

	Lm55:
	for x be Element of F_Complex holds
	the carrier of F_Rat c= the carrier of FQ_Ring(x) by Lm48;

	theorem Lm56:
	for x be Element of F_Complex holds
	[:RAT,RAT:] c= [:FQ(x),FQ(x):] & [:FQ(x),FQ(x):] c= [:COMPLEX,COMPLEX:]
	proof
	let x be Element of F_Complex;
	A1: the carrier of F_Rat c= the carrier of FQ_Ring(x) by Lm48;
	A2: FQ(x) c= the carrier of F_Complex;
	FQ(x) c= COMPLEX by A2,COMPLFLD:def 1;
	hence thesis by A1,ZFMISC_1:96;
	end;

	theorem Lm57:
	for x be Element of F_Complex holds
	the addF of F_Rat = (the addF of FQ_Ring(x))\|\|RAT
	proof
	let x be Element of F_Complex;
	thus the addF of F_Rat =
	addcomplex\|[:RAT,RAT:] by ZFMISC_1:96,RELAT_1:74,
	VECTSP_1:def 5,RING_3:2,GAUSSINT:13
	.= (the addF of FQ_Ring(x))\|\|RAT by Lm56,RELAT_1:74;
	end;

	theorem Lm58:
	for x be Element of F_Complex holds
	the multF of F_Rat = (the multF of FQ_Ring(x))\|\|RAT
	proof
	let x be Element of F_Complex;
	thus the multF of F_Rat
	= multcomplex\|[:RAT,RAT:] by ZFMISC_1:96,RELAT_1:74,
	VECTSP_1:def 5,RING_3:3,GAUSSINT:13
	.= (the multF of FQ_Ring(x))\|\|RAT by Lm56,RELAT_1:74;
	end;

	theorem
	for x be Element of F_Complex holds F_Rat is Subring of FQ_Ring(x)
	proof
	let x be Element of F_Complex;
	A1: the addF of F_Rat = (the addF of FQ_Ring(x))\|\|the carrier of F_Rat
	by Lm57;
	A2: the multF of F_Rat = (the multF of FQ_Ring(x))\|\|the carrier of F_Rat
	by Lm58;
	A3: 1.FQ_Ring(x) = 1.F_Complex by Lm52 .= 1.F_Rat by C0SP1:def 3,Th3;
	0.FQ_Ring(x) = 0.F_Rat by Lm48,Lm7,SUBSET_1:def 8;
	hence thesis by Lm55,A1,A2,A3,C0SP1:def 3;
	end;

	theorem Th80:
	for f,g be Element of Polynom-Ring K st
	f <> 0.Polynom-Ring K & {f}-Ideal is prime &
	not (g in {f}-Ideal) holds {f,g}-Ideal = the carrier of Polynom-Ring K
	proof
	let f,g be Element of Polynom-Ring K;
	assume that
	A1: f <> 0.Polynom-Ring K and
	A2: {f}-Ideal is prime and
	A4: not g in {f}-Ideal;
	assume
	A5: {f,g}-Ideal <> the carrier of Polynom-Ring K;
	Polynom-Ring K is PID; then
	consider h be Element of Polynom-Ring K such that
	A7: {f,g}-Ideal = {h}-Ideal by IDEAL_1:def 27;
	A8: {f}-Ideal c= {h}-Ideal & {g}-Ideal c= {h}-Ideal by A7,IDEAL_1:69;
	consider s be Element of Polynom-Ring K such that
	A9: f = h*s by RING_2:19,A8,GCD_1:def 1;
	consider t be Element of Polynom-Ring K such that
	A11:g = h*t by RING_2:19,A8,GCD_1:def 1;
	f is non zero Element of Polynom-Ring K by A1,STRUCT_0:def 12; then
	A13:f is prime by A2,RING_2:24;
	per cases by A9,A13;
	suppose f divides s; then
	consider u be Element of Polynom-Ring K such that
	A16: s = f*u by GCD_1:def 1;
	A17: f = f(uh) by GROUP_1:def 3,A9,A16;
	reconsider v = u*h as Element of Polynom-Ring K;
	f * 1.Polynom-Ring K - f*v = 0.Polynom-Ring K by RLVECT_1:5,A17;
	then
	f * (1.Polynom-Ring K -v) = 0.Polynom-Ring K by VECTSP_1:11; then
	1.Polynom-Ring K + (-v)=0.Polynom-Ring K by A1,VECTSP_2:def 1; then
	h divides 1.Polynom-Ring K by VECTSP_1:19,GCD_1:def 1; then
	A27: h is Unit of Polynom-Ring K by GCD_1:def 2;
	[#] Polynom-Ring K = the carrier of Polynom-Ring K;
	hence contradiction by A5,A7,A27,RING_2:20;
	end;
	suppose f divides h; then
	consider v be Element of Polynom-Ring K such that
	A31: h = f*v by GCD_1:def 1;
	g = f(vt) by A11,A31,GROUP_1:def 3;
	hence contradiction by A4,GCD_1:def 1,RING_2:18;
	end;
	end;

	theorem Th81:
	for f,g be Element of Polynom-Ring K holds
	f <> 0.Polynom-Ring K & {f}-Ideal is prime &
	not g in {f}-Ideal implies {f}-Ideal,{g}-Ideal are_co-prime
	proof
	let f,g be Element of Polynom-Ring K;
	{f,g}-Ideal = {f}-Ideal + {g}-Ideal by IDEAL_1:76;
	hence thesis by Th80;
	end;

	theorem Lm62:
	for x be Element of F_Complex,a be Element of FQ_Ring(x)
	ex g be Element of Polynom-Ring F_Rat st a = hom_Ext_eval(x,F_Rat).g
	proof
	let x be Element of F_Complex;
	let a be Element of FQ_Ring(x);
	ex g1 be object st g1 in dom hom_Ext_eval(x,F_Rat) &
	a = hom_Ext_eval(x,F_Rat).g1 by FUNCT_1:def 3;
	hence thesis;
	end;

	theorem Th83:
	for x,a be Element of F_Complex st a <> 0.F_Complex &
	a in the carrier of FQ_Ring(x)
	ex g be Element of Polynom-Ring F_Rat
	st not g in Ann_Poly(x,F_Rat) & a = hom_Ext_eval(x,F_Rat).g
	proof
	let x,a be Element of F_Complex;
	set M = {p where p is Polynomial of F_Rat:Ext_eval(p,x)=0.F_Complex};
	assume that
	A1: a <> 0.F_Complex and
	A2: a in the carrier of FQ_Ring(x);
	consider g be Element of Polynom-Ring F_Rat such that
	A3: a = hom_Ext_eval(x,F_Rat).g by A2,Lm62;
	take g;
	thus not g in Ann_Poly(x,F_Rat)
	proof
	assume g in Ann_Poly(x,F_Rat);
	then consider g1 be Polynomial of F_Rat such that
	A5: g1 = g and
	A6: Ext_eval(g1,x)=0.F_Complex;
	thus contradiction by A1,A6,A3,A5,Def9;
	end;
	thus thesis by A3;
	end;

	theorem Th84:
	for x,a be Element of F_Complex st x is algebraic & a <> 0.F_Complex &
	a in the carrier of FQ_Ring(x)
	ex f,g be Element of Polynom-Ring F_Rat
	st {f}-Ideal = Ann_Poly(x,F_Rat) & not(g in Ann_Poly(x,F_Rat)) &
	a = hom_Ext_eval(x,F_Rat).g &
	{f}-Ideal,{g}-Ideal are_co-prime
	proof
	let x,a be Element of F_Complex;
	assume that
	A1: x is algebraic and
	A2: a <> 0.F_Complex and
	A3: a in the carrier of FQ_Ring(x);
	consider f be Element of Polynom-Ring F_Rat such that
	A4: {f}-Ideal = Ann_Poly(x,F_Rat) by Th34,Th3;
	consider g be Element of Polynom-Ring F_Rat such that
	A5: not(g in Ann_Poly(x,F_Rat)) and
	A6: a = hom_Ext_eval(x,F_Rat).g by Th83,A2,A3;
	A7: {f}-Ideal is prime by A4,A1,Th3,Th39;
	A8: f <> 0.Polynom-Ring F_Rat by A1,A4,Th35,IDEAL_1:47;
	{f}-Ideal,{g}-Ideal are_co-prime by A4,A5,A7,A8,Th81;
	hence thesis by A4,A5,A6;
	end;

	theorem Th85:
	for x,a be Element of F_Complex st x is algebraic & a <> 0.F_Complex &
	a in the carrier of FQ_Ring(x) holds
	ex b be Element of F_Complex st b in the carrier of FQ_Ring(x)
	& a*b = 1.F_Complex
	proof
	let x,a be Element of F_Complex;
	set COPolynomFRat = the carrier of Polynom-Ring F_Rat;
	set M = {h where h is Polynomial of F_Rat:Ext_eval(h,x)=0.F_Complex};
	assume that
	A1: x is algebraic and
	A2: a <> 0.F_Complex and
	A3: a in the carrier of FQ_Ring(x);
	consider f,g be Element of Polynom-Ring F_Rat such that
	A4: {f}-Ideal = Ann_Poly(x,F_Rat) and
	not(g in Ann_Poly(x,F_Rat)) and
	A6: a = hom_Ext_eval(x,F_Rat).g and
	A7: {f}-Ideal,{g}-Ideal are_co-prime by A1,A2,A3,Th84;
	1.Polynom-Ring F_Rat in {f}-Ideal+{g}-Ideal by A7; then
	1.Polynom-Ring F_Rat in {p+q where p,q is Element of Polynom-Ring F_Rat:
	p in {f}-Ideal & q in {g}-Ideal} by IDEAL_1:def 19; then
	consider p,q be Element of Polynom-Ring F_Rat such that
	A10: 1.Polynom-Ring F_Rat = p+q and
	A11: p in {f}-Ideal and
	A12: q in {g}-Ideal;
	A14: {g}-Ideal = the set of all g*s where s is Element of Polynom-Ring F_Rat
	by IDEAL_1:64;
	consider s be Element of Polynom-Ring F_Rat such that
	A15: q = g * s by A12,A14;
	reconsider p1=p,q1=q, g1=g,s1=s as Polynomial of F_Rat
	by POLYNOM3:def 10;
	A16: p+q = p1+q1 by POLYNOM3:def 10;
	consider p2 be Polynomial of F_Rat such that
	A17: p2 = p and
	A18: Ext_eval(p2,x)=0.F_Complex by A4,A11;
	set b = Ext_eval(s1,x);
	A20: b = hom_Ext_eval(x,F_Rat).s1 by Def9;
	A21: dom hom_Ext_eval(x,F_Rat) = the carrier of Polynom-Ring F_Rat
	by FUNCT_2:def 1;
	A22: b in the carrier of FQ_Ring(x) by A20,A21,FUNCT_1:def 3;
	1.F_Complex = Ext_eval(1_.(F_Rat),x) by Th3,Th18
	.= Ext_eval(p1+q1,x) by A10,POLYNOM3:def 10,A16
	.= 0.F_Complex + Ext_eval(q1,x) by A17,A18,Th3,Th19
	.= Ext_eval(g1 *'s1,x) by A15,POLYNOM3:def 10
	.= Ext_eval(g1,x) * Ext_eval(s1,x) by Th3,Th24
	.= a*b by A6,Def9;
	hence thesis by A22;
	end;

	theorem
	for x be Element of F_Complex st x is algebraic holds FQ_Ring(x) is Field
	proof
	let x be Element of F_Complex;
	assume
	A1: x is algebraic;
	for a be Element of FQ_Ring(x) st a <> 0.FQ_Ring(x) holds
	a is left_invertible
	proof
	let a be Element of FQ_Ring(x);
	assume a <> 0.FQ_Ring(x); then
	A4: a <> 0.F_Complex by SUBSET_1:def 8;
	a in FQ(x); then
	reconsider y = a as Element of F_Complex;
	consider b be Element of F_Complex such that
	A5: b in the carrier of FQ_Ring(x) and
	A6: y*b = 1.F_Complex by A1,A4,Th85;
	reconsider a1=y,b1 = b as Element of FQ_Ring(x) by A5;
	b1*a1 = 1.F_Complex by A6,Th50
	.= 1.FQ_Ring(x) by Lm52;
	hence thesis;
	end;
	then FQ_Ring(x) is almost_left_invertible;
	hence FQ_Ring(x) is Field;
	end;