Datasets:

hoskinson-center
/

proof-pile

	:: Fix Point Theorem for Compact Spaces
	:: by Alicia de la Cruz

	environ

	vocabularies NUMBERS, XBOOLE_0, METRIC_1, FUNCT_1, REAL_1, CARD_1, ARYTM_3,
	PRE_TOPC, XXREAL_0, RELAT_1, STRUCT_0, FUNCOP_1, PCOMPS_1, RCOMP_1,
	SUBSET_1, POWER, SETFAM_1, TARSKI, ARYTM_1, FINSET_1, ORDINAL1, SEQ_1,
	VALUED_1, ORDINAL2, SEQ_2, ALI2, NAT_1, ASYMPT_1;
	notations TARSKI, XBOOLE_0, SUBSET_1, ORDINAL1, NUMBERS, XCMPLX_0, XREAL_0,
	FINSET_1, SETFAM_1, RELAT_1, FUNCT_1, FUNCT_2, FUNCOP_1, STRUCT_0,
	METRIC_1, PRE_TOPC, POWER, COMPTS_1, PCOMPS_1, TOPS_2, VALUED_1, SEQ_1,
	SEQ_2, XXREAL_0, REAL_1, NAT_1;
	constructors SETFAM_1, FUNCOP_1, FINSET_1, XXREAL_0, REAL_1, NAT_1, SEQ_2,
	POWER, TOPS_2, COMPTS_1, PCOMPS_1, VALUED_1, PARTFUN1, BINOP_2, RVSUM_1,
	COMSEQ_2, SEQ_1, RELSET_1;
	registrations SUBSET_1, ORDINAL1, NUMBERS, XXREAL_0, MEMBERED, STRUCT_0,
	METRIC_1, PCOMPS_1, VALUED_1, FUNCT_2, XREAL_0, SEQ_1, SEQ_2, RELSET_1,
	FUNCOP_1;
	requirements REAL, NUMERALS, SUBSET, BOOLE, ARITHM;
	definitions TARSKI, TOPS_2, ORDINAL1, XBOOLE_0, FINSET_1;
	equalities XBOOLE_0, SUBSET_1, STRUCT_0;
	theorems METRIC_1, SUBSET_1, PCOMPS_1, COMPTS_1, POWER, SEQ_2, SEQ_4,
	SERIES_1, SETFAM_1, SEQ_1, PRE_TOPC, TOPS_1, FINSET_1, XREAL_1, XXREAL_0,
	XBOOLE_0, XREAL_0, FUNCT_1, FUNCT_2;
	schemes SUBSET_1, SEQ_1, DOMAIN_1, NAT_1;

	begin

	definition
	let M be non empty MetrSpace;
	let f be Function of M, M;
	attr f is contraction means
	:Def1:
	ex L being Real st 0 < L & L < 1 &
	for x,y being Point of M holds dist(f.x,f.y) <= L * dist(x,y);
	end;

	registration
	let M be non empty MetrSpace;
	cluster constant -> contraction for Function of M,M;
	coherence
	proof
	let f be Function of M,M such that
	A1: f is constant;
	take 1/2;
	thus 0<1/2 & 1/2<1;
	let z,y be Point of M;
	dom f = the carrier of M by FUNCT_2:def 1;
	then f.z = f.y by A1,FUNCT_1:def 10;
	then
	A2: dist(f.z,f.y) = 0 by METRIC_1:1;
	dist(z,y)>=0 by METRIC_1:5;
	hence thesis by A2;
	end;
	end;

	registration
	let M be non empty MetrSpace;
	cluster constant for Function of M, M;
	existence
	proof
	M --> the Point of M is constant;
	hence thesis;
	end;
	end;

	definition
	let M be non empty MetrSpace;
	mode Contraction of M is contraction Function of M, M;
	end;

	::$N Banach fixed-point theorem
	theorem
	for M being non empty MetrSpace
	for f being Contraction of M st TopSpaceMetr(M) is compact
	ex c being Point of M st f.c = c &
	for x being Point of M st f.x = x holds x = c
	proof
	let M be non empty MetrSpace;
	let f be Contraction of M;
	set x0 = the Point of M;
	set a=dist(x0,f.x0);
	consider L being Real such that
	A1: 0<L and
	A2: L<1 and
	A3: for x,y being Point of M holds dist(f.x,f.y)<=L*dist(x,y) by Def1;
	assume
	A4: TopSpaceMetr(M) is compact;
	now
	deffunc F(Nat) = L to_power ($1+1);
	defpred P[set] means ex n being Nat st $1 = { x where x is
	Point of M : dist(x,f.x) <= a*L to_power n};
	assume a <> 0;
	consider F being Subset-Family of TopSpaceMetr(M) such that
	A5: for B being Subset of TopSpaceMetr(M) holds B in F iff P[B] from
	SUBSET_1:sch 3;
	defpred P[Point of M] means dist($1,f.($1)) <= a*L to_power (0+1);
	A6: F is closed
	proof
	let B be Subset of TopSpaceMetr(M);
	A7: TopSpaceMetr(M)=TopStruct (#the carrier of M,Family_open_set(M)#)
	by PCOMPS_1:def 5;
	then reconsider V = B` as Subset of M;
	assume B in F;
	then consider n being Nat such that
	A8: B= { x where x is Point of M : dist(x,f.x) <= a*L to_power n} by A5;
	for x being Point of M st x in V
	ex r being Real st r>0 & Ball(x,r) c= V
	proof
	let x be Point of M;
	assume x in V;
	then not x in B by XBOOLE_0:def 5;
	then dist(x,f.x)>a*L to_power n by A8;
	then
	A9: dist(x,f.x)-a*L to_power n>0 by XREAL_1:50;
	take r = (dist(x,f.x)-a*L to_power n)/2;
	thus r>0 by A9,XREAL_1:215;
	let z be object;
	assume
	A10: z in Ball(x,r);
	then reconsider y=z as Point of M;
	dist(x,y)<r by A10,METRIC_1:11;
	then 2dist(x,y)<2r by XREAL_1:68;
	then
	A11: dist(y,f.y) + 2dist(x,y)< dist(y,f.y) + 2r by XREAL_1:6;
	dist(x,y) + dist(y,f.y) >= dist(x,f.y) by METRIC_1:4;
	then
	A12: (dist(x,y) + dist(y,f.y)) + dist(f.y,f.x) >=
	dist(x,f.y) + dist(f.y,f.x) by XREAL_1:6;
	dist(f.y,f.x)<=Ldist(y,x) & Ldist(y,x)<=dist(y,x)
	by A2,A3,METRIC_1:5,XREAL_1:153;
	then dist(f.y,f.x)<=dist(y,x) by XXREAL_0:2;
	then dist(f.y,f.x)+dist(y,x) <= dist(y,x)+dist(y,x) by XREAL_1:6;
	then
	A13: dist(y,f.y) + (dist(y,x) + dist(f.y,f.x)) <= dist(y,f.y) + 2*dist
	(y,x) by XREAL_1:7;
	dist(x,f.y) + dist(f.y,f.x) >= dist(x,f.x) by METRIC_1:4;
	then dist(y,f.y)+dist(x,y)+dist(f.y,f.x)>=dist(x,f.x)
	by A12,XXREAL_0:2;
	then dist(y,f.y)+2*dist(x,y)>=dist(x,f.x) by A13,XXREAL_0:2;
	then
	dist(x,f.x)-2r = aL to_power n & dist(y,f.y)+2*r>dist(x,f.x)
	by A11,XXREAL_0:2;
	then
	not ex x being Point of M st y = x & dist(x,f.x)<= a*L to_power n
	by XREAL_1:19;
	then not y in B by A8;
	hence thesis by A7,SUBSET_1:29;
	end;
	then B` in Family_open_set(M) by PCOMPS_1:def 4;
	then B` is open by A7,PRE_TOPC:def 2;
	hence thesis by TOPS_1:3;
	end;
	A14: TopSpaceMetr(M)=TopStruct (#the carrier of M,Family_open_set(M)#)
	by PCOMPS_1:def 5;
	A15: {x where x is Point of M:P[x]}is Subset of M from DOMAIN_1:sch 7;
	F is centered
	proof
	thus F <> {} by A5,A14,A15;
	defpred P[Nat] means
	{ x where x is Point of M : dist(x,f.x)
	<= a*L to_power $1}<>{};
	let G be set such that
	A16: G <> {} and
	A17: G c= F and
	A18: G is finite;
	G is c=-linear
	proof
	let B,C be set;
	assume that
	A19: B in G and
	A20: C in G;
	B in F by A17,A19;
	then consider n being Nat such that
	A21: B= { x where x is Point of M : dist(x,f.x) <= a*L to_power n} by A5;
	C in F by A17,A20;
	then consider m being Nat such that
	A22: C= { x where x is Point of M : dist(x,f.x) <= a*L to_power m} by A5;
	A23: for n,m being Nat st n<=m holds L to_power m <= L to_power n
	proof
	let n,m be Nat such that
	A24: n<=m;
	per cases by A24,XXREAL_0:1;
	suppose
	n<m;
	hence thesis by A1,A2,POWER:40;
	end;
	suppose
	n=m;
	hence thesis;
	end;
	end;
	A25: for n,m being Nat st n<=m holds aL to_power m <= aL
	to_power n
	proof
	A26: a>=0 by METRIC_1:5;
	let n,m be Nat;
	assume n<=m;
	hence thesis by A23,A26,XREAL_1:64;
	end;
	now
	per cases;
	case
	A27: n<=m;
	thus C c= B
	proof
	let y be object;
	assume y in C;
	then consider x being Point of M such that
	A28: y = x and
	A29: dist(x,f.x) <= a*L to_power m by A22;
	aL to_power m <= aL to_power n by A25,A27;
	then dist(x,f.x) <= a*L to_power n by A29,XXREAL_0:2;
	hence thesis by A21,A28;
	end;
	end;
	case
	A30: m<=n;
	thus B c= C
	proof
	let y be object;
	assume y in B;
	then consider x being Point of M such that
	A31: y = x and
	A32: dist(x,f.x) <= a*L to_power n by A21;
	aL to_power n <= aL to_power m by A25,A30;
	then dist(x,f.x) <= a*L to_power m by A32,XXREAL_0:2;
	hence thesis by A22,A31;
	end;
	end;
	end;
	hence B c= C or C c= B;
	end;
	then consider m being set such that
	A33: m in G and
	A34: for C being set st C in G holds m c= C by A16,A18,FINSET_1:11;
	A35: m c= meet G by A16,A34,SETFAM_1:5;
	A36: for k being Nat st P[k] holds P[k+1]
	proof
	let k be Nat;
	set z = the Element of { x where x is Point of M :
	dist(x,f.x) <= a*L to_power k};
	A37: L(aL to_power k)=a(LL to_power k)
	.=a(L to_power kL to_power 1) by POWER:25
	.= a*L to_power (k+1) by A1,POWER:27;
	assume { x where x is Point of M : dist(x,f.x) <= a*L to_power k}<> {};
	then z in { x where x is Point of M : dist(x,f.x) <= a*L to_power k};
	then consider y being Point of M such that
	y=z and
	A38: dist(y,f.y)<= a*L to_power k;
	A39: dist(f.y,f.(f.y)) <= L*dist(y,f.y) by A3;
	Ldist(y,f.y) <= L(a*L to_power k) by A1,A38,XREAL_1:64;
	then dist(f.y,f.(f.y)) <= a*L to_power (k+1) by A37,A39,XXREAL_0:2;
	then
	f.y in { x where x is Point of M : dist(x,f.x) <= a*L to_power (k +1)};
	hence thesis;
	end;
	dist(x0,f.x0) = a1 .= aL to_power 0 by POWER:24;
	then x0 in { x where x is Point of M : dist(x,f.x) <= a*L to_power 0};
	then
	A40: P[0];
	A41: for k being Nat holds P[k] from NAT_1:sch 2(A40,A36);
	m in F by A17,A33;
	then m <> {} by A5,A41;
	hence thesis by A35;
	end;
	then meet F <> {} by A4,A6,COMPTS_1:4;
	then consider c9 being Point of TopSpaceMetr(M) such that
	A42: c9 in meet F by SUBSET_1:4;
	reconsider c = c9 as Point of M by A14;
	reconsider dc = dist(c,f.c) as Element of REAL by XREAL_0:def 1;
	set r = seq_const dist(c,f.c);
	consider s9 being Real_Sequence such that
	A43: for n being Nat holds s9.n= F(n) from SEQ_1:sch 1;
	set s = a (#) s9;
	lim s9=0 by A1,A2,A43,SERIES_1:1;
	then
	A44: lim s = a*0 by A1,A2,A43,SEQ_2:8,SERIES_1:1
	.= 0;
	A45: now
	let n be Nat;
	defpred P[Point of M] means dist($1,f.$1) <= a*L to_power (n+1);
	set B = { x where x is Point of M : P[x]};
	B is Subset of M from DOMAIN_1:sch 7;
	then B in F by A5,A14;
	then c in B by A42,SETFAM_1:def 1;
	then
	A46: ex x being Point of M st c = x & dist(x,f.x) <= a*L to_power ( n+1 );
	s.n = a*s9.n by SEQ_1:9
	.= a*L to_power (n+1) by A43;
	hence r.n <= s.n by A46,SEQ_1:57;
	end;
	s is convergent by A1,A2,A43,SEQ_2:7,SERIES_1:1;
	then
	A47: lim r <= lim s by A45,SEQ_2:18;
	r.0=dist(c,f.c) by SEQ_1:57;
	then dist(c,f.c)<=0 by A44,A47,SEQ_4:25;
	then dist(c,f.c)=0 by METRIC_1:5;
	hence ex c being Point of M st dist(c,f.c) = 0;
	end;
	then consider c being Point of M such that
	A48: dist(c,f.c) = 0;
	take c;
	thus
	A49: f.c =c by A48,METRIC_1:2;
	let x be Point of M;
	assume
	A50: f.x=x;
	A51: dist(x,c)>=0 by METRIC_1:5;
	assume x<>c;
	then dist(x,c)<>0 by METRIC_1:2;
	then L*dist(x,c)<dist(x,c) by A2,A51,XREAL_1:157;
	hence contradiction by A3,A49,A50;
	end;