:: A Case Study of Transport Urysohn's Lemma from TopSpace Defined with
:: Open Sets to TopSpace Defined with Neighborhoods
:: by Roland Coghetto
::
:: Received October 25, 2020
:: Copyright (c) 2020-2021 Association of Mizar Users
:: (Stowarzyszenie Uzytkownikow Mizara, Bialystok, Poland).
:: This code can be distributed under the GNU General Public Licence
:: version 3.0 or later, or the Creative Commons Attribution-ShareAlike
:: License version 3.0 or later, subject to the binding interpretation
:: detailed in file COPYING.interpretation.
:: See COPYING.GPL and COPYING.CC-BY-SA for the full text of these
:: licenses, or see http://www.gnu.org/licenses/gpl.html and
:: http://creativecommons.org/licenses/by-sa/3.0/.
environ
vocabularies XBOOLE_0, SUBSET_1, FUNCT_1, RELAT_1, CARD_FIL, STRUCT_0,
PRE_TOPC, RCOMP_1, ORDINAL2, ZFMISC_1, PCOMPS_1, FINTOPO7, FUNCOP_1,
FINTOPO2, TARSKI, CARDFIL2, TOPS_1, TMAP_1, SETFAM_1, CONNSP_2, NATTRA_1,
TOPMETR, REAL_1, XXREAL_0, CARD_1, MEMBERED, XREAL_0, XXREAL_1, ARYTM_1,
ARYTM_3, RLVECT_3, CANTOR_1, NUMBERS, METRIC_1, FRECHET, FILTER_0, NAT_1,
FINTOPO8;
notations FUNCT_2, NUMBERS, SUBSET_1, TARSKI, FUNCT_1, RELSET_1, XBOOLE_0,
STRUCT_0, CARD_FIL, FINTOPO2, ZFMISC_1, PRE_TOPC, CARDFIL2, CONNSP_2,
TOPS_1, TDLAT_3, XREAL_0, TOPMETR, XXREAL_0, XCMPLX_0, RCOMP_1, TOPS_2,
CANTOR_1, FINTOPO7, METRIC_1, PCOMPS_1, ORDINAL1, FRECHET;
constructors CARDFIL2, FINTOPO7, TOPS_1, TDLAT_3, SUPINF_2, TOPMETR, FUNCOP_1,
RCOMP_1, TOPS_2, CANTOR_1, FRECHET, YELLOW_8;
registrations MEMBERED, TOPMETR, VALUED_0, YELLOW13, STRUCT_0, PRE_TOPC,
TOPS_1, FINTOPO7, SUBSET_1, RELSET_1, FUNCT_2, TEX_1, XREAL_0, CANTOR_1,
METRIC_1, PCOMPS_1, ORDINAL1, FRECHET, ZFMISC_1;
requirements ARITHM, NUMERALS, SUBSET, BOOLE, REAL;
definitions TARSKI;
equalities STRUCT_0, XBOOLE_0;
expansions TARSKI, SUBSET_1, XBOOLE_0;
theorems XREAL_0, URYSOHN1, PRE_TOPC, FINTOPO7, FUNCOP_1, CARDFIL2, XBOOLE_0,
CARD_FIL, FUNCT_2, RELAT_1, FUNCT_1, TARSKI, XBOOLE_1, CONNSP_2, TOPS_1,
URYSOHN3, TOPMETR, MEMBERED, FRECHET, TOPGEN_5, JORDAN6, CANTOR_1,
TOPREAL6, XREAL_1, XXREAL_0, METRIC_1, NAT_1, INTEGRA6, FINTOPO2;
schemes FUNCT_2;
begin :: Some trivial results in TopSpace
reserve T for TopSpace,
A,B for Subset of T;
theorem Th1:
A misses B implies Int A misses Int B
proof
assume
A1: A misses B;
Int A c= A & Int B c= B by TOPS_1:16;
then Int A /\ Int B c= {} by A1,XBOOLE_1:27;
hence thesis;
end;
begin :: Some redefinitions: NTopSpace
definition
mode NTopSpace is FMT_TopSpace;
end;
notation
let X be non empty TopSpace;
synonym Top2NTop X for TopSpace2FMT X;
end;
notation
let X be FMT_TopSpace;
synonym NTop2Top X for FMT2TopSpace X;
end;
begin :: Alignment of concepts between TopSpace and NTopSpace
Lm1:
for TX being non empty TopSpace for O being open Subset of TX holds
O is open Subset of Top2NTop TX
proof
let TX be non empty TopSpace;
let O be open Subset of TX;
O in the topology of TX by PRE_TOPC:def 2;
then O in Family_open_set(Top2NTop TX) by FINTOPO7:def 15;
then O in the set of all OO where OO is open Subset of Top2NTop TX
by FINTOPO7:def 11;
then ex OO be open Subset of Top2NTop TX st O = OO;
hence thesis;
end;
Lm2:
for NTX being non empty NTopSpace holds
[#]NTX is open & {} NTX is open
proof
let NTX be NTopSpace;
reconsider X = NTop2Top NTX as non empty TopSpace;
now
thus [#] NTX = the carrier of NTop2Top NTX by FINTOPO7:def 16;
thus {} NTX = {} NTop2Top NTX;
the carrier of NTop2Top NTX in the topology of NTop2Top NTX
by PRE_TOPC:def 1;
hence the carrier of NTop2Top NTX is open Subset of NTop2Top NTX
by PRE_TOPC:def 2;
end;
then reconsider S1 = [#] NTX, S2 = {} NTX as open Subset of X;
Top2NTop X = NTX by FINTOPO7:25;
then S1 is open Subset of NTX & S2 is open Subset of NTX by Lm1;
hence thesis;
end;
registration
let NTX be non empty NTopSpace;
cluster [#] NTX -> open;
coherence by Lm2;
cluster {} NTX -> open;
coherence by Lm2;
end;
definition
let NTX be U_FMT_filter non empty strict FMT_Space_Str;
let x be Element of NTX;
redefine func U_FMT x -> Filter of the carrier of NTX;
coherence by FINTOPO7:def 2;
end;
definition
let NTX be U_FMT_filter non empty strict FMT_Space_Str;
let F be Filter of the carrier of NTX;
func lim_filter F -> Subset of NTX equals
{x where x is Point of NTX: F is_filter-finer_than U_FMT x};
correctness
proof
set S = {x where x is Point of NTX: F is_filter-finer_than U_FMT x};
now
let x be object;
assume x in S;
then ex y be Point of NTX st x = y & F is_filter-finer_than U_FMT y;
hence x in the carrier of NTX;
end;
then S c= the carrier of NTX;
hence thesis;
end;
end;
definition
let NTX,NTY be U_FMT_filter non empty strict FMT_Space_Str,
f be Function of NTX,NTY,
F be Filter of the carrier of NTX;
func lim_filter(f,F) -> Subset of NTY equals
lim_filter filter_image(f,F);
coherence;
end;
definition
let NT be NTopSpace;
let A be Subset of NT;
let x be Point of NT;
pred x is_interior_point_of A means
A is a_neighborhood of x;
end;
definition
let NT be NTopSpace;
let A be Subset of NT;
let x be Point of NT;
pred x is_adherent_point_of A means
for V be Element of U_FMT x holds V meets A;
end;
definition
let NT be NTopSpace;
let A be Subset of NT;
func Int A -> Subset of NT equals
{x where x is Point of NT: x is_interior_point_of A};
coherence
proof
set S = {x where x is Point of NT: x is_interior_point_of A};
S c= the carrier of NT
proof
let o be object;
assume o in S;
then ex x be Point of NT st o = x & x is_interior_point_of A;
hence thesis;
end;
hence thesis;
end;
end;
definition
let NTX,NTY be NTopSpace,
f be Function of NTX,NTY,
x be Point of NTX;
pred f is_continuous_at x means
for F being Filter of the carrier of NTX st x in lim_filter F holds
f.x in lim_filter(f,F);
end;
definition
let NTX,NTY be NTopSpace,
f be Function of NTX,NTY;
attr f is continuous means
for x being Point of NTX holds f is_continuous_at x;
end;
Lm3:
for NTX,NTY being NTopSpace, a being Point of NTY holds
NTX --> a is continuous
proof
let NTX,NTY be NTopSpace;
let a be Point of NTY;
set f = NTX --> a;
now
thus dom f = the carrier of NTX by FUNCOP_1:13;
hereby
let x be Point of NTX;
now
let F be Filter of the carrier of NTX;
assume x in lim_filter F;
{M where M is Subset of NTY: f"M in F}
= {M where M is Subset of NTY: a in M}
proof
set S1 = {M where M is Subset of NTY: f"M in F},
S2 = {M where M is Subset of NTY: a in M};
now
now
let x be object;
assume x in S1;
then consider M be Subset of NTY such that
A1: x = M and
A2: f"M in F;
(a in M implies f"M = the carrier of NTX) &
(not a in M implies f"M = {}) & not {} in F
by FUNCOP_1:14,16,CARD_FIL:def 1;
hence x in S2 by A1,A2;
end;
hence S1 c= S2;
now
let x be object;
assume x in S2;
then consider M be Subset of NTY such that
A3: x = M and
A4: a in M;
(a in M implies f"M = the carrier of NTX) &
the carrier of NTX in F by FUNCOP_1:14,CARD_FIL:5;
hence x in S1 by A3,A4;
end;
hence S2 c= S1;
end;
hence thesis;
end;
then
A5: filter_image(f,F) = {M where M is Subset of NTY: a in M}
by CARDFIL2:def 13;
reconsider S3 = {M where M is Subset of NTY: a in M}
as Filter of the carrier of NTY by A5;
set S4 = {y where y is Point of NTY:
S3 is_filter-finer_than U_FMT y};
U_FMT a c= S3
proof
now
let x be object;
assume
A6: x in U_FMT a;
then reconsider y = x as Subset of NTY;
a in y by A6,FINTOPO7:def 3;
hence x in S3;
end;
hence thesis;
end;
then S3 is_filter-finer_than U_FMT a by CARDFIL2:def 6;
then a in S4;
hence f.x in lim_filter(f,F) by FUNCOP_1:7,A5;
end;
hence f is_continuous_at x;
end;
end;
hence NTX --> a is continuous;
end;
registration
let NTX,NTY be NTopSpace;
cluster continuous for Function of NTX,NTY;
existence
proof
set a = the Point of NTY;
NTX --> a is continuous by Lm3;
hence thesis;
end;
end;
Lm4:
for NT being NTopSpace
for A being Subset of NT
for x being Point of NT holds
(x is_interior_point_of A iff
ex O be open Subset of NT st x in O & O c= A)
proof
let NT be NTopSpace;
let A be Subset of NT;
let x be Point of NT;
now
assume ex O be open Subset of NT st x in O & O c= A;
then consider O be open Subset of NT such that
A1: x in O and
A2: O c= A;
O in U_FMT x & U_FMT x is Filter of the carrier of NT
by A1,FINTOPO7:def 1;
then A in U_FMT x by A2,CARD_FIL:def 1;
hence x is_interior_point_of A by FINTOPO7:def 5;
end;
hence thesis by FINTOPO7:15;
end;
Lm5:
for NT being NTopSpace
for A being Subset of NT holds
Int A = union {O where O is open Subset of NT: O c= A}
proof
let NT be NTopSpace;
let A be Subset of NT;
set B = union {O where O is open Subset of NT: O c= A};
now
now
let o be object;
assume o in Int A;
then consider x be Point of NT such that
A1: o = x and
A2: x is_interior_point_of A;
consider O be open Subset of NT such that
A3: x in O and
A4: O c= A by A2,Lm4;
O in {O where O is open Subset of NT: O c= A} by A4;
hence o in B by A1,A3,TARSKI:def 4;
end;
hence Int A c= B;
now
let o be object;
assume o in B;
then consider X be set such that
A5: o in X and
A6: X in {O where O is open Subset of NT: O c= A} by TARSKI:def 4;
consider O be open Subset of NT such that
A7: X = O and
A8: O c= A by A6;
reconsider x = o as Point of NT by A5,A7;
x is_interior_point_of A by A5,A7,A8,Lm4;
hence o in Int A;
end;
hence B c= Int A;
end;
hence thesis;
end;
registration
let NT be NTopSpace;
let A be Subset of NT;
cluster Int A -> open;
coherence
proof
set a = {O where O is open Subset of NT: O c= A};
now
let o be object;
assume o in a;
then ex O be open Subset of NT st o = O & O c= A;
hence o in bool the carrier of NT;
end;
then a c= bool the carrier of NT;
then reconsider a as Subset-Family of NT;
now
let o be object;
assume o in a;
then consider O be open Subset of NT such that
A1: o = O and O c= A;
O in the set of all O where O is open Subset of NT;
hence o in Family_open_set(NT) by A1,FINTOPO7:def 11;
end;
then a c= Family_open_set(NT);
then union a in Family_open_set(NT) by FINTOPO7:14;
then union a in the set of all O where O is open Subset of NT
by FINTOPO7:def 11;
then ex O be open Subset of NT st union a = O;
hence thesis by Lm5;
end;
end;
definition
let NT be NTopSpace;
let A be Subset of NT;
func Cl A -> Subset of NT equals
{x where x is Point of NT: x is_adherent_point_of A};
coherence
proof
set S = {x where x is Point of NT: x is_adherent_point_of A};
S c= the carrier of NT
proof
let o be object;
assume o in S;
then ex x be Point of NT st o = x & x is_adherent_point_of A;
hence thesis;
end;
hence thesis;
end;
end;
definition
let NTX be NTopSpace;
let A be Subset of NTX;
attr A is closed means
:Def9:
([#] NTX) \ A is open Subset of NTX;
end;
registration
let NTX be NTopSpace;
cluster closed for Subset of NTX;
existence
proof
[#] NTX = [#] NTX \ {} NTX;
hence thesis by Def9;
end;
end;
registration
let NTX be NTopSpace;
cluster [#] NTX -> closed for Subset of NTX;
coherence
proof
[#] NTX \ [#] NTX = {} NTX by XBOOLE_1:37;
hence thesis;
end;
cluster {} NTX -> closed for Subset of NTX;
coherence;
end;
registration
let NTX be NTopSpace;
cluster non empty closed for Subset of NTX;
existence
proof
[#] NTX is non empty & [#] NTX is closed;
hence thesis;
end;
end;
definition
let S,T be non empty TopSpace;
let f be Function of S,T;
func Top2NTop f -> Function of Top2NTop S,Top2NTop T equals f;
coherence
proof
the carrier of S = the carrier of Top2NTop S &
the carrier of T = the carrier of Top2NTop T by FINTOPO7:def 15;
hence thesis;
end;
end;
Lm6:
for NT being NTopSpace
for A, B being Subset of NT st B = [#]NT \ A holds
A is open iff B is closed
proof
let NT be NTopSpace;
let A, B be Subset of NT;
assume
A1: B = [#] NT \ A;
now
hereby
assume
A2: A is open;
[#] NT \ B = [#] NT /\ A by A1,XBOOLE_1:48
.= A by XBOOLE_1:28;
hence B is closed by A2;
end;
hereby
assume
A3: B is closed;
then reconsider NB = [#]NT \ B as Subset of NT;
NB = [#] NT /\ A by A1,XBOOLE_1:48
.= A by XBOOLE_1:28;
hence A is open by A3;
end;
end;
hence thesis;
end;
Lm7:
for TX being non empty TopSpace for F being closed Subset of TX holds
F is closed Subset of Top2NTop TX
proof
let TX be non empty TopSpace;
let F be closed Subset of TX;
set NTX = Top2NTop TX;
A1: [#]NTX = [#] TX by FINTOPO7:def 15;
reconsider O = [#]TX \ F as open Subset of TX by PRE_TOPC:def 3;
reconsider NO = O as open Subset of NTX by Lm1;
[#]NTX \ NO = [#]NTX /\ F by A1,XBOOLE_1:48
.= F by A1,XBOOLE_1:28;
hence thesis by Lm6,FINTOPO7:def 15;
end;
Lm8:
for NT being NTopSpace
for A, B being Subset of NT st A = [#]NT \ B holds
A is open iff B is closed;
Lm9:
for NTX being NTopSpace for O being open Subset of NTX holds
O is open Subset of NTop2Top NTX
proof
let NTX be NTopSpace;
let O be open Subset of NTX;
O in the set of all OO where OO is open Subset of NTX;
then O in Family_open_set(NTX) by FINTOPO7:def 11;
then O in the topology of NTop2Top NTX by FINTOPO7:def 16;
hence thesis by PRE_TOPC:def 2;
end;
Lm10:
for NTX being NTopSpace for F being closed Subset of NTX holds
F is closed Subset of NTop2Top NTX
proof
let NTX be NTopSpace;
let F be closed Subset of NTX;
reconsider TX = NTop2Top NTX as non empty TopSpace;
A1: [#]NTX = [#] TX by FINTOPO7:def 16;
reconsider O = [#] NTX \ F as Subset of NTX by XBOOLE_1:36;
reconsider O as open Subset of NTX by Lm8;
reconsider NO = O as open Subset of TX by Lm9;
reconsider NF = [#] TX \ NO as Subset of TX by XBOOLE_1:36;
A2: [#] TX \ NF = [#]TX /\ NO by XBOOLE_1:48
.= NO by XBOOLE_1:28;
[#]TX \ NO = [#]TX /\ F by A1,XBOOLE_1:48
.= F by A1,XBOOLE_1:28;
hence thesis by A2,PRE_TOPC:def 3;
end;
Lm11:
for NTX,NTY being NTopSpace
for x being Point of NTX
for y being Point of NTY
for f being Function of NTX,NTY st f is_continuous_at x & y = f.x holds
(for V being Element of U_FMT y ex W being Element of U_FMT x st f.:W c= V)
proof
let NTX,NTY be NTopSpace;
let x be Point of NTX;
let y be Point of NTY;
let f be Function of NTX,NTY;
assume that
A1: f is_continuous_at x and
A2: y = f.x;
U_FMT x is Filter of the carrier of NTX & x in lim_filter(U_FMT x);
then f.x in lim_filter(f,U_FMT x) by A1;
then consider z be Point of NTY such that
A3: f.x = z and
A4: filter_image(f,U_FMT x) is_filter-finer_than U_FMT z;
A5: U_FMT y c= filter_image(f,U_FMT x) by A3,A4,A2,CARDFIL2:def 6;
for V be Element of U_FMT y holds ex W be Element of U_FMT x st f.:W c= V
proof
let V be Element of U_FMT y;
V in filter_image(f,U_FMT x) by A5;
then V in {M where M is Subset of NTY: f"(M) in U_FMT x}
by CARDFIL2:def 13;
then consider M be Subset of NTY such that
A6: V = M and
A7: f"M in U_FMT x;
set W = f"M;
f.:W c= M by FUNCT_1:75;
hence thesis by A6,A7;
end;
hence thesis;
end;
Lm12:
for NTX,NTY being NTopSpace
for A being Subset of NTX
for B being Subset of NTY
for x being Point of NTX
for y being Point of NTY
for f being Function of NTX,NTY st f is_continuous_at x &
x is_adherent_point_of A & y = f.x & B = f.:A holds y is_adherent_point_of B
proof
let NTX,NTY be NTopSpace;
let A be Subset of NTX;
let B be Subset of NTY;
let x be Point of NTX;
let y be Point of NTY;
let f be Function of NTX,NTY;
assume that
A1: f is_continuous_at x and
A2: x is_adherent_point_of A and
A3: y = f.x and
A4: B = f.:A;
now
let V be Element of U_FMT y;
consider W be Element of U_FMT x such that
A5: f.:W c= V by A1,A3,Lm11;
A6: f.:f"V c= V by FUNCT_1:75;
now
now
dom f = the carrier of NTX by FUNCT_2:def 1;
hence W c= f"(f.:W) by FUNCT_1:76;
thus W in U_FMT x;
thus U_FMT x is Filter of the carrier of NTX;
end;
hence f"(f.:W) in U_FMT x by CARD_FIL:def 1;
thus f"(f.:W) c= f"V by A5,RELAT_1:143;
end;
then f"V in U_FMT x by CARD_FIL:def 1;
then f"V meets A by A2;
then f"V /\ A is non empty;
then consider a be object such that A7: a in f"V /\ A;
now
dom f = the carrier of NTX & a in A
by A7,XBOOLE_0:def 4,FUNCT_2:def 1;
hence a in dom f;
thus a in f"V by A7,XBOOLE_0:def 4;
end;
then
A8: f.a in f.:f"V by FUNCT_1:def 6;
dom f = the carrier of NTX & a in A by A7,XBOOLE_0:def 4,FUNCT_2:def 1;
then f.a in f.:A by FUNCT_1:def 6;
hence V meets B by A4,A8,A6,XBOOLE_0:def 4;
end;
hence thesis;
end;
Lm13:
for NTX,NTY being NTopSpace
for A being Subset of NTX
for f being continuous Function of NTX,NTY
holds f.:(Cl A) c= Cl(f.:A)
proof
let NTX,NTY be NTopSpace;
let A be Subset of NTX;
let f be continuous Function of NTX,NTY;
now
let o be object;
assume o in f.:(Cl A);
then consider x be object such that
A1: x in dom f and
A2: x in Cl A and
A3: o = f.x by FUNCT_1:def 6;
consider x9 be Point of NTX such that
A4: x = x9 and
A5: x9 is_adherent_point_of A by A2;
f.x in rng f by A1,FUNCT_1:3;
then reconsider y = f.x as Point of NTY;
f is continuous;
then y is_adherent_point_of f.:A by A4,A5,Lm12;
hence o in Cl(f.:A) by A3;
end;
hence thesis;
end;
Lm14:
for NT being NTopSpace
for A, B being Subset of NT st B = [#] NT \ A holds
[#] NT \ Cl A = Int B
proof
let NT be NTopSpace;
let A,B be Subset of NT;
assume
A1: B = [#] NT \ A;
now
now
let o be object;
assume
A2: o in [#] NT \ Cl A;
then
A3: o in [#] NT & not o in Cl A by XBOOLE_0:def 5;
reconsider x = o as Point of NT by A2,XBOOLE_0:def 5;
not x is_adherent_point_of A by A3;
then consider V be Element of U_FMT x such that
A4: not V meets A;
reconsider V as Subset of NT;
now
let x be object;
assume
A5: x in V;
not x in A by A4,A5,XBOOLE_0:def 4;
hence x in [#] NT \ A by A5,XBOOLE_0:def 5;
end;
then
A6: V c= [#] NT \ A;
reconsider NA = [#] NT \ A as Subset of NT by XBOOLE_1:36;
NA in U_FMT x by A6,CARD_FIL:def 1;
then x is_interior_point_of NA by FINTOPO7:def 5;
hence o in Int B by A1;
end;
hence [#]NT \ Cl A c= Int B;
now
let o be object;
assume o in Int B;
then consider x be Point of NT such that
A7: o = x and
A8: x is_interior_point_of B;
A9: B in U_FMT x by A8,FINTOPO7:def 5;
not x in {x where x is Point of NT: x is_adherent_point_of A}
proof
assume x in {x where x is Point of NT: x is_adherent_point_of A};
then consider y be Point of NT such that
A10: x = y and
A11: y is_adherent_point_of A;
ex z be object st z in B & z in A by A9,A10,A11,XBOOLE_0:3;
hence contradiction by A1,XBOOLE_0:def 5;
end;
hence o in [#] NT \ Cl A by A7,XBOOLE_0:def 5;
end;
hence Int B c=[#]NT \ Cl A;
end;
hence [#] NT \ Cl A = Int B;
end;
Lm15:
for NT being NTopSpace
for A being Subset of NT holds
Int A c= A
proof
let NT be NTopSpace;
let A be Subset of NT;
A1: Int A = union {O where O is open Subset of NT: O c= A} by Lm5;
now
let o be object;
assume o in Int A;
then consider X be set such that
A2: o in X and
A3: X in {O where O is open Subset of NT: O c= A} by A1,TARSKI:def 4;
consider O be open Subset of NT such that
A4: X = O and
A5: O c= A by A3;
thus o in A by A2,A4,A5;
end;
hence thesis;
end;
Lm16:
for NT being NTopSpace
for A being Subset of NT
for B being open Subset of NT st B c= A holds B c= Int A
proof
let NT be NTopSpace;
let A be Subset of NT;
let B be open Subset of NT;
set C = {O where O is open Subset of NT: O c= A};
assume B c= A;
then
A1: B in C;
Int A = union C by Lm5;
hence thesis by A1,TARSKI:def 4;
end;
Lm17:
for NT being NTopSpace
for A, B being Subset of NT st A c= B holds Int A c= Int B
proof
let NT be NTopSpace;
let A, B be Subset of NT;
assume
A1: A c= B;
Int A c= A by Lm15;
then Int A c= B by A1;
hence thesis by Lm16;
end;
Lm18:
for NT being NTopSpace
for A,B being Subset of NT st A c= B holds Cl A c= Cl B
proof
let NT be NTopSpace;
let A,B be Subset of NT;
assume
A1: A c= B;
reconsider NCA = [#] NT \ Cl A as Subset of NT by XBOOLE_1:36;
reconsider NCB = [#] NT \ Cl B as Subset of NT by XBOOLE_1:36;
reconsider NA = [#] NT \ A as Subset of NT by XBOOLE_1:36;
reconsider NB = [#] NT \ B as Subset of NT by XBOOLE_1:36;
NB c= NA & NCA = Int NA & NCB = Int NB by Lm14,A1,XBOOLE_1:34;
then
A2: NCB c= NCA by Lm17;
now
thus Cl A = [#] NT /\ Cl A by XBOOLE_1:28
.= [#] NT \ NCA by XBOOLE_1:48;
thus Cl B = [#] NT /\ Cl B by XBOOLE_1:28
.= [#] NT \ NCB by XBOOLE_1:48;
end;
hence thesis by A2,XBOOLE_1:34;
end;
Lm19:
for NT being NTopSpace
for A being Subset of NT holds
(A is open iff Int A = A)
proof
let NT be NTopSpace;
let A be Subset of NT;
hereby
assume
A1: A is open;
A2: Int A = union {O where O is open Subset of NT: O c= A} by Lm5;
now
let o be object;
assume
A3: o in A;
A in {O where O is open Subset of NT: O c= A} by A1;
hence o in Int A by A2,A3,TARSKI:def 4;
end;
then A c= Int A;
hence Int A = A by Lm15;
end;
assume Int A = A;
hence A is open;
end;
Lm20:
for NTX being NTopSpace
for A being closed Subset of NTX holds Cl A = A
proof
let NTX be NTopSpace;
let A be closed Subset of NTX;
reconsider NA = ([#] NTX \ A) as open Subset of NTX by Def9;
Cl A = [#] NTX /\ Cl A by XBOOLE_1:28
.= [#] NTX \ ([#] NTX \ Cl A) by XBOOLE_1:48
.= [#] NTX \ Int NA by Lm14
.= [#] NTX \ NA by Lm19
.= [#] NTX /\ A by XBOOLE_1:48
.= A by XBOOLE_1:28;
hence thesis;
end;
Lm21:
for NT being NTopSpace
for A being Subset of NT holds
A c= Cl A
proof
let NT be NTopSpace;
let A be Subset of NT;
reconsider NCA = [#]NT \ Cl A as Subset of NT by XBOOLE_1:36;
reconsider NA = [#]NT \ A as Subset of NT by XBOOLE_1:36;
Int NA c= NA by Lm15;
then NCA c= NA by Lm14;
then [#]NT \ NA c= [#]NT \ NCA by XBOOLE_1:34;
then [#]NT /\ A c= [#]NT \ NCA by XBOOLE_1:48;
then A c= [#]NT \ NCA by XBOOLE_1:28;
then A c= [#]NT /\ Cl A by XBOOLE_1:48;
hence thesis by XBOOLE_1:28;
end;
Lm22:
for NTX being NTopSpace
for A being Subset of NTX st Cl A = A holds A is closed Subset of NTX
proof
let NTX be NTopSpace;
let A be Subset of NTX;
assume
A1: Cl A = A;
reconsider NA = ([#] NTX \ A) as Subset of NTX by XBOOLE_1:36;
A2: Cl A = [#] NTX /\ Cl A by XBOOLE_1:28
.= [#] NTX \ ([#] NTX \ Cl A) by XBOOLE_1:48
.= [#] NTX \ Int NA by Lm14;
Int NA = Int NA /\ [#] NTX by XBOOLE_1:28
.= NA by A1,A2,XBOOLE_1:48;
then A is closed;
hence thesis;
end;
Lm23:
for NTX,NTY being NTopSpace
for f being Function of NTX,NTY st
(for A being Subset of NTX holds f.:(Cl A) c= Cl(f.:A)) holds
(for S being closed Subset of NTY holds f"S is closed Subset of NTX)
proof
let NTX,NTY be NTopSpace;
let f be Function of NTX,NTY;
assume
A1: for A be Subset of NTX holds f.:(Cl A) c= Cl(f.:A);
let S9 be closed Subset of NTY;
reconsider S = f"(S9) as Subset of NTX;
f.:(Cl S) c= Cl (f.:S) & Cl (f.:S) c= Cl S9 by A1,Lm18,FUNCT_1:75;
then f.:(Cl S) c= Cl S9;
then f.:(Cl S) c= S9 by Lm20;
then
A2: f"(f.:Cl S) c= f" S9 by RELAT_1:143;
dom f = [#] NTX by FUNCT_2:def 1;
then Cl S c= f"(f.:Cl S) by FUNCT_1:76;
then Cl S c= S & S c= Cl S by A2,Lm21;
then S = Cl S;
hence thesis by Lm22;
end;
Lm24:
for NTX,NTY being NTopSpace
for f being Function of NTX,NTY st
(for S being closed Subset of NTY holds f"S is closed Subset of NTX)
holds
(for S being open Subset of NTY holds f"S is open Subset of NTX)
proof
let NTX,NTY be NTopSpace;
let f be Function of NTX,NTY;
assume
A1: for S being closed Subset of NTY holds f"S is closed Subset of NTX;
now
let S be open Subset of NTY;
reconsider NS = [#] NTY \ S as closed Subset of NTY
by XBOOLE_1:36,Lm6;
reconsider fNS = f"NS as closed Subset of NTX by A1;
fNS = f"([#] NTY) \ f"(S) by FUNCT_1:69
.= [#] NTX \ f"(S) by FUNCT_2:40;
then [#] NTX \ fNS = [#] NTX /\ f"(S) by XBOOLE_1:48;
then f"S = [#] NTX \ fNS by XBOOLE_1:28;
hence f"S is open Subset of NTX by Lm8;
end;
hence thesis;
end;
Lm25:
for NTX,NTY being NTopSpace
for x being Point of NTX
for y being Point of NTY
for f being Function of NTX,NTY st y = f.x &
(for V being Element of U_FMT y ex W being Element of U_FMT x st f.:W c= V)
holds f is_continuous_at x
proof
let NTX,NTY be NTopSpace;
let x be Point of NTX;
let y be Point of NTY;
let f be Function of NTX,NTY;
assume that
A1: y = f.x and
A2: for V be Element of U_FMT y ex W being Element of U_FMT x st f.:W c= V;
now
let F be Filter of the carrier of NTX;
assume x in lim_filter F;
then consider x9 be Point of NTX such that
A3: x = x9 and
A4: F is_filter-finer_than U_FMT x9;
A5: U_FMT x c= F by A3,A4,CARDFIL2:def 6;
now
let o be object;
assume o in U_FMT y;
then reconsider V = o as Element of U_FMT y;
consider W be Element of U_FMT x such that
A6: f.:W c= V by A2;
A7: W in F by A5;
reconsider M = f.:W as Subset of NTY;
A8: W c= f"(M) by FUNCT_2:42;
f"(M) c= f"(V) by A6,RELAT_1:143;
then W c= f"(V) by A8;
then f"(V) in F by A7,CARD_FIL:def 1;
then V in {M where M is Subset of NTY: f"M in F};
hence o in filter_image(f,F) by CARDFIL2:def 13;
end;
then U_FMT y c= filter_image(f,F);
then filter_image(f,F) is_filter-finer_than U_FMT y by CARDFIL2:def 6;
hence y in lim_filter(f,F);
end;
hence thesis by A1;
end;
Lm26:
for NTX,NTY being NTopSpace
for f being Function of NTX,NTY st
(for S being open Subset of NTY holds f"S is open Subset of NTX)
holds f is continuous
proof
let NTX,NTY be NTopSpace;
let f be Function of NTX,NTY;
assume
A1: for S being open Subset of NTY holds f"S is open Subset of NTX;
now
let x be Point of NTX;
dom f = the carrier of NTX by FUNCT_2:def 1;
then f.x in rng f by FUNCT_1:3;
then reconsider y = f.x as Point of NTY;
now
let V be Element of U_FMT y;
consider W9 be Element of U_FMT y such that
A2: for z be Element of NTY st z is Element of W9 holds
V is Element of U_FMT z by FINTOPO7:def 4;
reconsider V9 = V as Subset of NTY;
now
thus W9 is non empty by FINTOPO7:def 3;
now
let x be Element of NTY;
assume x in W9;
then V is Element of U_FMT x by A2;
hence V9 in U_FMT x;
end;
hence V9 is a_neighborhood of W9 by FINTOPO7:def 6;
end;
then consider O be open Subset of NTY such that
A3: W9 c= O and
A4: O c= V9 by FINTOPO7:16;
now
now
thus y in O by A3,FINTOPO7:def 3;
dom f = the carrier of NTX by FUNCT_2:def 1;
hence x in dom f;
end;
then x in f"O by FUNCT_1:def 7;
hence f"O in U_FMT x by A1,FINTOPO7:def 1;
f.:f"O c= O by FUNCT_1:75;
hence f.:f"O c= V by A4;
end;
hence ex W being Element of U_FMT x st f.:W c= V;
end;
hence f is_continuous_at x by Lm25;
end;
hence thesis;
end;
Lm27:
for NTX,NTY being NTopSpace
for f being Function of NTX,NTY holds
(f is continuous iff for O being closed Subset of NTY holds
f"O is closed Subset of NTX)
proof
let NTX,NTY be NTopSpace;
let f be Function of NTX,NTY;
hereby
assume f is continuous;
then for A being Subset of NTX holds f.:(Cl A) c= Cl(f.:A)
by Lm13;
hence for S being closed Subset of NTY holds f"S is closed Subset of NTX
by Lm23;
end;
assume for O being closed Subset of NTY holds f"O is closed Subset of NTX;
then for O being open Subset of NTY holds f"O is open Subset of NTX
by Lm24;
hence f is continuous by Lm26;
end;
definition
let TX being non empty TopSpace,
TY being non empty strict TopSpace;
let f be continuous Function of TX,TY;
redefine func Top2NTop f ->
continuous Function of Top2NTop TX,Top2NTop TY equals f;
correctness
proof
set NTX = Top2NTop TX,
NTY = Top2NTop TY;
reconsider f9 = Top2NTop f as Function of NTX,NTY;
now
let F be closed Subset of NTY;
reconsider F9 = F as closed Subset of NTop2Top NTY by Lm10;
reconsider TY9 = TY as non empty TopSpace;
NTop2Top NTY = TY9 by FINTOPO7:24;
then reconsider F9 as closed Subset of TY;
f"F9 is closed Subset of TX by PRE_TOPC:def 6;
hence f9"F is closed Subset of NTX by Lm7;
end;
hence thesis by Lm27;
end;
end;
definition
let NT be NTopSpace;
attr NT is T_2 means
:Def12:
for F being Filter of the carrier of NT holds
lim_filter F is trivial;
end;
registration
cluster T_2 for NTopSpace;
existence
proof
set T2 = the non empty T_2 TopSpace;
reconsider NTX = Top2NTop T2 as NTopSpace;
take NTX;
now
let F be Filter of the carrier of NTX;
set S = {x where x is Point of NTX: F is_filter-finer_than U_FMT x};
not ex x,y be object st x in lim_filter F & y in lim_filter F & x <> y
proof
let x,y be object;
assume that
A1: x in lim_filter F and
A2: y in lim_filter F and
A3: x <> y;
consider x9 be Point of NTX such that
A4: x = x9 and
A5: F is_filter-finer_than U_FMT x9 by A1;
consider y9 be Point of NTX such that
A6: y = y9 and
A7: F is_filter-finer_than U_FMT y9 by A2;
reconsider x99 = x9,y99 = y9 as Point of T2 by FINTOPO7:def 15;
consider G1,G2 be Subset of T2 such that
A8: G1 is open and
A9: G2 is open and
A10: x99 in G1 and
A11: y99 in G2 and
A12: G1 misses G2 by A3,A4,A6,PRE_TOPC:def 10;
reconsider G19 = G1, G29 = G2 as open Subset of NTX
by A8,A9,Lm1;
A13: G19 in U_FMT x9 & G29 in U_FMT y9 by A10,A11,FINTOPO7:def 1;
U_FMT x9 c= F & U_FMT y9 c= F by A5,A7,CARDFIL2:def 6;
then {} in F by A13,A12,CARD_FIL:def 1;
hence contradiction by CARD_FIL:def 1;
end;
hence lim_filter F is trivial;
end;
hence thesis;
end;
end;
definition
let NT be NTopSpace;
attr NT is normal means
:Def13:
for A,B being closed Subset of NT st A misses B holds
ex V being a_neighborhood of A,
W being a_neighborhood of B st V misses W;
end;
Lm28:
for T being T_2 non empty TopSpace holds Top2NTop T is T_2 NTopSpace
proof
let T be T_2 non empty TopSpace;
reconsider NT = Top2NTop T as NTopSpace;
now
let F be Filter of the carrier of NT;
set S = {x where x is Point of NT: F is_filter-finer_than U_FMT x};
not ex x,y be object st x in lim_filter F & y in lim_filter F & x <> y
proof
let x,y be object;
assume that
A1: x in lim_filter F and
A2: y in lim_filter F and
A3: x <> y;
consider x9 be Point of NT such that
A4: x = x9 and
A5: F is_filter-finer_than U_FMT x9 by A1;
consider y9 be Point of NT such that
A6: y = y9 and
A7: F is_filter-finer_than U_FMT y9 by A2;
reconsider x99 = x9,y99 = y9 as Point of T by FINTOPO7:def 15;
consider G1,G2 be Subset of T such that
A8: G1 is open and
A9: G2 is open and
A10: x99 in G1 and
A11: y99 in G2 and
A12: G1 misses G2 by A4,A6,A3,PRE_TOPC:def 10;
reconsider G19 = G1, G29 = G2 as open Subset of NT by A8,A9,Lm1;
A13: G19 in U_FMT x9 & G29 in U_FMT y9 by A10,A11,FINTOPO7:def 1;
U_FMT x9 c= F & U_FMT y9 c= F by A5,A7,CARDFIL2:def 6;
then G19 /\ G29 in F by A13,CARD_FIL:def 1;
hence contradiction by A12,CARD_FIL:def 1;
end;
hence lim_filter F is trivial;
end;
then NT is T_2;
hence thesis;
end;
Lm29:
for NTX being NTopSpace
for A being closed Subset of NTX holds A is closed Subset of NTop2Top NTX
proof
let NTX be NTopSpace;
let A be closed Subset of NTX;
reconsider T = NTop2Top NTX as TopSpace;
[#] NTX \ A is open Subset of NTX by Def9;
then [#] NTX \ A is open Subset of NTop2Top NTX by Lm9;
then reconsider A9 = ([#] T) \ A as open Subset of T by FINTOPO7:def 16;
([#] T) \ A9 = [#] T /\ A & A is Subset of T
by XBOOLE_1:48,FINTOPO7:def 16;
hence thesis by PRE_TOPC:def 3;
end;
definition
let NT be NTopSpace;
let x be Point of NT;
func NTop2Top x -> Point of NTop2Top NT equals x;
coherence by FINTOPO7:def 16;
end;
definition
let T be non empty TopSpace;
let x be Point of T;
func Top2NTop x -> Point of Top2NTop T equals x;
coherence by FINTOPO7:def 15;
end;
definition
let NT be NTopSpace;
let S be Subset of NT;
func NTop2Top S -> Subset of NTop2Top NT equals S;
coherence by FINTOPO7:def 16;
end;
definition
let T be non empty TopSpace;
let S be Subset of T;
func Top2NTop S -> Subset of Top2NTop T equals S;
coherence by FINTOPO7:def 15;
end;
Lm30:
for T being non empty strict TopSpace
for A being Subset of T holds Int A = Int Top2NTop A
proof
let T be non empty strict TopSpace;
let A be Subset of T;
reconsider NT = Top2NTop T as NTopSpace;
reconsider NA = Top2NTop A as Subset of NT;
now
now
let o be object;
assume
A1: o in Int NA;
then reconsider x = o as Point of NT;
consider y be Point of NT such that
A2: x = y and
A3: y is_interior_point_of NA by A1;
consider NO be open Subset of NT such that
A4: y in NO and
A5: NO c= NA by A3,Lm4;
reconsider y9 = NTop2Top y as Point of T
by FINTOPO7:24;
reconsider O = NO as open Subset of NTop2Top NT
by Lm9;
NTop2Top NT = T by FINTOPO7:24;
then reconsider O as open Subset of T;
y9 in O & O c= A by A4,A5;
then A is a_neighborhood of y9 by URYSOHN1:def 6;
hence o in Int A by CONNSP_2:def 1,A2;
end;
hence Int NA c= Int A;
now
let o be object;
assume
A6: o in Int A;
then reconsider x = o as Point of T;
consider O be Subset of T such that
A7: O is open and
A8: x in O and
A9: O c= A by A6,CONNSP_2:def 1,URYSOHN1:def 6;
reconsider y = Top2NTop x as Point of NT;
reconsider NO = O as open Subset of NT by A7,Lm1;
y in NO & NO c= NA by A8,A9;
then y is_interior_point_of NA by Lm4;
hence o in Int NA;
end;
hence Int A c= Int NA;
end;
hence thesis;
end;
Lm31:
for T being non empty strict TopSpace
for A,B being Subset of T st A is a_neighborhood of B holds
Top2NTop A is a_neighborhood of Top2NTop B
proof
let T be non empty strict TopSpace;
let A,B be Subset of T;
reconsider NT = Top2NTop T as NTopSpace;
reconsider TA = Top2NTop A,
TB = Top2NTop B as Subset of NT;
assume A is a_neighborhood of B;
then
A1: B c= Int A by CONNSP_2:def 2;
now
let x be Element of NT;
assume x in TB;
then x in Int A by A1;
then x in Int TA by Lm30;
then ex x9 be Point of NT st x = x9 & x9 is_interior_point_of TA;
hence TA in U_FMT x by FINTOPO7:def 5;
end;
hence thesis by FINTOPO7:def 6;
end;
registration
cluster non empty normal for NTopSpace;
existence
proof
set T = the discrete non empty strict TopSpace;
reconsider NT = Top2NTop T as NTopSpace;
reconsider NT as T_2 NTopSpace by Lm28;
A1: NTop2Top NT = T by FINTOPO7:24;
now
let A,B be closed Subset of NT;
assume
A2: A misses B;
reconsider TA = A, TB = B as closed Subset of T by A1,Lm29;
consider G1,G2 be Subset of T such that
A3: G1 is open and
A4: G2 is open and
A5: TA c= G1 and
A6: TB c= G2 and
A7: G1 misses G2 by A2,PRE_TOPC:def 12;
reconsider G1 as open Subset of T by A3;
reconsider G2 as open Subset of T by A4;
A8: TA c= Int G1 & TB c= Int G2 by A5,A6,TOPS_1:23;
reconsider V = G1,
W = G2 as open Subset of NT by Lm1;
Top2NTop G1 is a_neighborhood of Top2NTop TA &
Top2NTop G2 is a_neighborhood of Top2NTop TB
by A8,CONNSP_2:def 2,Lm31;
hence ex V be a_neighborhood of A, W be a_neighborhood of B st
V misses W by A7;
end;
then NT is normal;
hence thesis;
end;
end;
definition
let TX,TY be NTopSpace;
let f be Function of TX,TY;
func NTop2Top f -> Function of NTop2Top TX,NTop2Top TY equals f;
coherence
proof
the carrier of TX = the carrier of NTop2Top TX &
the carrier of TY = the carrier of NTop2Top TY
by FINTOPO7:def 16;
hence thesis;
end;
end;
definition
func FMT_R^1 -> NTopSpace equals Top2NTop R^1;
coherence;
end;
theorem
the carrier of FMT_R^1 = REAL by TOPMETR:17,FINTOPO7:def 15;
registration
cluster FMT_R^1 -> real-membered;
coherence
proof
now
let x be object;
assume x in the carrier of FMT_R^1;
then reconsider x9 = x as Element of FMT_R^1;
x9 in the carrier of Top2NTop R^1;
then x in the carrier of R^1 by FINTOPO7:def 15;
hence x is real;
end;
hence thesis by TOPMETR:def 8,MEMBERED:def 3;
end;
end;
begin :: Some properties of NTopSpace
reserve NT,NTX,NTY for NTopSpace,
A,B for Subset of NT,
O for open Subset of NT,
a for Point of NT,
XA for Subset of NTX,
YB for Subset of NTY,
x for Point of NTX,
y for Point of NTY,
f for Function of NTX,NTY,
fc for continuous Function of NTX,NTY;
theorem
O is open Subset of NTop2Top NT by Lm9;
theorem
A is Subset of NTop2Top NT by FINTOPO7:def 16;
theorem
[#]NT is open & {} NT is open;
theorem
NT --> y is continuous by Lm3;
theorem
(a is_interior_point_of A iff
ex O be open Subset of NT st a in O & O c= A) by Lm4;
theorem
a in O implies a is_interior_point_of O by Lm4;
theorem
Int A = union {O where O is open Subset of NT: O c= A} by Lm5;
theorem
Int A c= A by Lm15;
theorem
A c= B implies Int A c= Int B by Lm17;
theorem Th12:
A is open iff Int A = A
proof
hereby
assume
A1: A is open;
A2: Int A = union {O where O is open Subset of NT: O c= A} by Lm5;
now
let o be object;
assume
A3: o in A;
A in {O where O is open Subset of NT: O c= A} by A1;
hence o in Int A by A2,A3,TARSKI:def 4;
end;
then A c= Int A;
hence Int A = A by Lm15;
end;
assume Int A = A;
hence A is open;
end;
theorem
Int A = Int Int A by Th12;
theorem Th14:
for NT be non empty strict NTopSpace
for A be Subset of NT
for x be Point of NT st
A is a_neighborhood of x holds Int A is open a_neighborhood of x
proof
let NT be non empty strict NTopSpace;
let A be Subset of NT;
let x be Point of NT;
assume A is a_neighborhood of x;
then x is_interior_point_of A;
then x in Int A;
then x in Int Int A by Th12;
then ex y be Point of NT st x = y & y is_interior_point_of Int A;
then reconsider IA = Int A as a_neighborhood of x;
IA is open a_neighborhood of x;
hence thesis;
end;
theorem
filter_image(f,U_FMT x) =
{M where M is Subset of NTY: f"(M) in U_FMT x} by CARDFIL2:def 13;
theorem
(f is_continuous_at x & y = f.x) implies
(for V being Element of U_FMT y ex W being Element of U_FMT x st f.:W c= V)
by Lm11;
theorem
y = f.x &
(for V being Element of U_FMT y ex W being Element of U_FMT x st f.:W c= V)
implies f is_continuous_at x by Lm25;
theorem
y = f.x implies
(f is_continuous_at x iff
(for V being Element of U_FMT y ex W being Element of U_FMT x st f.:W c= V))
by Lm11,Lm25;
theorem
(f is_continuous_at x &
x is_adherent_point_of XA & y = f.x & YB = f.:XA) implies
y is_adherent_point_of YB by Lm12;
theorem
fc.:(Cl XA) c= Cl(fc.:XA) by Lm13;
theorem
for A being closed Subset of NT holds A is closed Subset of NTop2Top NT
by Lm29;
theorem
B = [#] NT \ A implies [#] NT \ Cl A = Int B by Lm14;
theorem
B = [#] NT \ A implies [#] NT \ Int A = Cl B
proof
assume
A1: B = [#] NT \ A;
reconsider C = [#] NT \ B as Subset of NT by XBOOLE_1:36;
A2: [#] NT \ B = [#] NT /\ A by A1,XBOOLE_1:48
.= A by XBOOLE_1:28;
Cl B = [#] NT /\ Cl B by XBOOLE_1:28
.= [#] NT \ ([#] NT \ Cl B) by XBOOLE_1:48
.= [#] NT \ Int A by A2,Lm14;
hence thesis;
end;
theorem
A c= Cl A by Lm21;
theorem
A is closed iff Cl A = A by Lm20,Lm22;
theorem
A c= B implies Cl A c= Cl B by Lm18;
theorem
(for XA being Subset of NTX holds f.:(Cl XA) c= Cl(f.:XA)) implies
(for S being closed Subset of NTY holds f"S is closed Subset of NTX)
by Lm23;
theorem
B = [#]NT \ A implies (A is open iff B is closed) by Lm6;
theorem
A = [#]NT \ B implies (A is open iff B is closed);
theorem
(for S being closed Subset of NTY holds f"S is closed Subset of NTX)
implies
(for S being open Subset of NTY holds f"S is open Subset of NTX)
by Lm24;
theorem
(for S being open Subset of NTY holds f"S is open Subset of NTX)
implies f is continuous by Lm26;
theorem
f is continuous iff for O being open Subset of NTY holds
f"O is open Subset of NTX
proof
hereby
assume f is continuous;
then for A being Subset of NTX holds f.:(Cl A) c= Cl(f.:A)
by Lm13;
then for S being closed Subset of NTY holds f"S is closed Subset of NTX
by Lm23;
hence for O being open Subset of NTY holds f"O is open Subset of NTX
by Lm24;
end;
assume for O being open Subset of NTY holds f"O is open Subset of NTX;
hence f is continuous by Lm26;
end;
theorem
f is continuous iff for O being closed Subset of NTY holds
f"O is closed Subset of NTX by Lm27;
theorem Th34:
Int A = Int NTop2Top A
proof
set NA = A;
reconsider T = NTop2Top NT as non empty TopSpace;
reconsider A9 = NTop2Top NA as Subset of T;
now
now
let o be object;
assume o in Int NA;
then consider y be Point of NT such that
A1: o = y and
A2: y is_interior_point_of NA;
consider NO be open Subset of NT such that
A3: y in NO and
A4: NO c= NA by A2,Lm4;
reconsider O = NO as open Subset of T by Lm9;
y in O by A3;
then reconsider y9 = y as Point of T;
y9 in O & O c= A9 by A3,A4;
then A is a_neighborhood of y9 by URYSOHN1:def 6;
hence o in Int A9 by CONNSP_2:def 1,A1;
end;
hence Int NA c= Int A9;
now
let o be object;
assume
A5: o in Int A9;
then reconsider x = o as Point of T;
consider O be Subset of T such that
A6: O is open and
A7: x in O and
A8: O c= A9 by A5,CONNSP_2:def 1,URYSOHN1:def 6;
Top2NTop T = NT by FINTOPO7:25;
then reconsider NO = O as open Subset of NT
by A6,Lm1;
x in NO by A7;
then reconsider y = x as Point of NT;
y in NO & NO c= NA by A7,A8;
then y is_interior_point_of NA by Lm4;
hence o in Int NA;
end;
hence Int A9 c= Int NA;
end;
hence thesis;
end;
theorem
A is a_neighborhood of a implies NTop2Top A is a_neighborhood of NTop2Top a
proof
reconsider T = NTop2Top NT as non empty TopSpace;
reconsider TA = NTop2Top A as Subset of T;
reconsider Tx = NTop2Top a as Point of T;
assume A is a_neighborhood of a;
then a is_interior_point_of A;
then a in Int A;
then Tx in Int TA by Th34;
hence thesis by CONNSP_2:def 1;
end;
theorem Th36:
A is a_neighborhood of B implies
NTop2Top A is a_neighborhood of NTop2Top B
proof
assume
A1: A is a_neighborhood of B;
reconsider T = NTop2Top NT as TopSpace;
reconsider TA = NTop2Top A, TB = NTop2Top B as Subset of T;
per cases;
suppose B is non empty;
then consider O be open Subset of NT such that
A2: B c= O and
A3: O c= A by A1,FINTOPO7:16;
reconsider O9 = O as open Subset of T by Lm9;
O9 c= Int TA by A3,TOPS_1:24;
then TB c= Int TA by A2;
hence thesis by CONNSP_2:def 2;
end;
suppose B is empty;
then TB c= Int TA;
hence thesis by CONNSP_2:def 2;
end;
end;
theorem
A misses B implies NTop2Top A misses NTop2Top B;
theorem
A misses B implies Int A misses Int B
proof
assume
A1: A misses B;
Int A c= A & Int B c= B by Lm15;
then Int A /\ Int B c= {} by A1,XBOOLE_1:27;
hence thesis;
end;
reserve NT for T_2 NTopSpace;
theorem Th39:
for x,y being Point of NT st x <> y ex Vx being Element of U_FMT x,
Vy being Element of U_FMT y st Vx misses Vy
proof
let x,y be Point of NT;
assume
A1: x <> y;
now
assume
A2: for Vx be Element of U_FMT x, Vy be Element of U_FMT y holds Vx meets Vy;
A3: now
let Vx be Element of U_FMT x, Vy be Element of U_FMT y;
Vx meets Vy by A2;
hence Vx /\ Vy is non empty;
end;
reconsider X = the carrier of NT as non empty set;
reconsider Ux = U_FMT x as Filter of X;
reconsider Uy = U_FMT y as Filter of X;
consider F be Filter of X such that
A4: F is_filter-finer_than Ux and
A5: F is_filter-finer_than Uy by A3,CARDFIL2:58;
reconsider x9 = x, y9 = y as Element of X;
reconsider F as Filter of the carrier of NT;
A6: x9 in lim_filter F & y9 in lim_filter F by A4,A5;
lim_filter F is empty or lim_filter F is trivial by Def12;
hence contradiction by A1,A6;
end;
hence thesis;
end;
theorem
NTop2Top NT is T_2 non empty strict TopSpace
proof
reconsider T = NTop2Top NT as non empty TopSpace;
now
let p, q be Point of T;
assume
A1: p <> q;
reconsider p9 = p, q9 = q as Point of NT by FINTOPO7:def 16;
set Sp = lim_filter U_FMT p9,
Sq = lim_filter U_FMT q9;
consider Vx be Element of U_FMT p9, Vy be Element of U_FMT q9 such that
A2: Vx misses Vy by A1,Th39;
p9 is_interior_point_of Vx by FINTOPO7:def 5;
then consider Ox be open Subset of NT such that
A3: p9 in Ox and
A4: Ox c= Vx by Lm4;
q9 is_interior_point_of Vy by FINTOPO7:def 5;
then consider Oy be open Subset of NT such that
A5: q9 in Oy and
A6: Oy c= Vy by Lm4;
reconsider G1 = Ox, G2 = Oy as open Subset of T by Lm9;
G1 misses G2 by A4,A6,A2,XBOOLE_1:64;
hence ex G1,G2 be Subset of T st G1 is open & G2 is open &
p in G1 & q in G2 & G1 misses G2 by A3,A5;
end;
hence thesis by PRE_TOPC:def 10;
end;
theorem Th41:
for NT being non empty normal NTopSpace holds NTop2Top NT is normal
proof
let NT be non empty normal NTopSpace;
reconsider T = NTop2Top NT as non empty TopSpace;
now
let F1,F2 be Subset of T;
assume that
A1: F1 is closed and
A2: F2 is closed and
A3: F1 misses F2;
Top2NTop T = NT by FINTOPO7:25;
then reconsider F19 = F1,F29 = F2 as closed Subset of NT
by A1,A2,Lm7;
consider V be a_neighborhood of F19,
W be a_neighborhood of F29 such that
A4: V misses W by A3,Def13;
A5: NTop2Top F19 c= Int NTop2Top V & NTop2Top F29 c= Int NTop2Top W
by Th36,CONNSP_2:def 2;
reconsider G1 = Int NTop2Top V,
G2 = Int NTop2Top W as open Subset of T;
thus ex G1,G2 be Subset of T st G1 is open & G2 is open &
F1 c= G1 & F2 c= G2 & G1 misses G2 by A4,A5,Th1;
end;
hence thesis by PRE_TOPC:def 12;
end;
registration
let NT be non empty normal NTopSpace;
cluster NTop2Top NT -> normal;
coherence by Th41;
end;
begin :: Some properties between TopSpace and NTopSpace
reserve T for non empty TopSpace,
A,B for Subset of T,
F for closed Subset of T,
O for open Subset of T;
theorem
A is Subset of Top2NTop T by FINTOPO7:def 15;
theorem
F is closed Subset of Top2NTop T by Lm7;
theorem
O is open Subset of Top2NTop T by Lm1;
theorem
A misses B implies Top2NTop A misses Top2NTop B;
theorem
for T being T_2 non empty TopSpace holds Top2NTop T is T_2 NTopSpace
by Lm28;
reserve T for non empty strict TopSpace,
A,B for Subset of T,
x for Point of T;
theorem
Int A = Int Top2NTop A by Lm30;
theorem
A is a_neighborhood of B implies Top2NTop A is a_neighborhood of Top2NTop B
by Lm31;
theorem
A is a_neighborhood of x implies Top2NTop A is a_neighborhood of Top2NTop x
proof
reconsider NT = Top2NTop T as NTopSpace;
reconsider NA = Top2NTop A as Subset of NT;
reconsider Nx = Top2NTop x as Point of NT;
assume A is a_neighborhood of x;
then x in Int A by CONNSP_2:def 1;
then Nx in Int NA by Lm30;
then ex y be Point of NT st Nx = y & y is_interior_point_of NA;
hence thesis;
end;
theorem TH:
for T being non empty normal strict TopSpace holds Top2NTop T is normal
proof
let T be non empty normal strict TopSpace;
reconsider NT = Top2NTop T as NTopSpace;
now
let NA,NB be closed Subset of NT;
assume
A1: NA misses NB;
NTop2Top NT = T by FINTOPO7:24;
then reconsider A = NTop2Top NA,
B = NTop2Top NB as closed Subset of T by Lm29;
consider G1,G2 be Subset of T such that
A2: G1 is open and
A3: G2 is open and
A4: A c= G1 and
A5: B c= G2 and
A6: G1 misses G2 by A1,PRE_TOPC:def 12;
reconsider V = Top2NTop G1, W = Top2NTop G2 as open Subset of NT
by Lm1,A2,A3;
A7: A c= Int G1 & B c= Int G2 by A2,A3,A4,A5,TOPS_1:23;
reconsider V = G1,
W = G2 as open Subset of NT by A2,A3,Lm1;
Top2NTop G1 is a_neighborhood of Top2NTop A &
Top2NTop G2 is a_neighborhood of Top2NTop B
by A7,CONNSP_2:def 2,Lm31;
hence ex V be a_neighborhood of NA, W be a_neighborhood of NB st
V misses W by A6;
end;
hence thesis;
end;
registration
let T be non empty normal strict TopSpace;
cluster Top2NTop T -> normal;
coherence by TH;
end;
begin :: Transport from R^1 to FMT_R^1
reserve A for Subset of FMT_R^1,
x for Point of FMT_R^1,
y for Point of RealSpace,
z for Point of TopSpaceMetr RealSpace,
r for Real;
theorem
NTop2Top FMT_R^1 = R^1 by FINTOPO7:24;
theorem Th52:
the carrier of FMT_R^1 = REAL by TOPMETR:17,FINTOPO7:def 15;
theorem
for NT being NTopSpace for f being Function of NT,FMT_R^1 holds
NTop2Top f is Function of NTop2Top NT,R^1
by FINTOPO7:24;
theorem
for T being non empty TopSpace for f being Function of T,R^1 holds
Top2NTop f is Function of Top2NTop T,Top2NTop R^1;
theorem Th55:
A is open iff for x being Real st x in A
ex r st r > 0 & ].x - r, x + r.[ c= A
proof
A is Subset of NTop2Top Top2NTop R^1 by FINTOPO7:def 16;
then reconsider A9 = A as Subset of R^1 by FINTOPO7:24;
hereby
assume A is open;
then A is open Subset of NTop2Top FMT_R^1 &
NTop2Top FMT_R^1 = R^1 by FINTOPO7:24,Lm9;
hence for x being Real st x in A
ex r being Real st r > 0 & ].x - r, x + r.[ c= A by FRECHET:8;
end;
assume for x being Real st x in A
ex r being Real st r > 0 & ].x - r, x + r.[ c= A;
then A9 is open by FRECHET:8;
hence A is open by Lm1;
end;
theorem
{].a,b.[ where a,b is Real: a < b} is Basis of R^1 by TOPGEN_5:72;
theorem Th57:
{].a,b.[ where a,b is Real: a < b} is Basis of FMT_R^1
proof
set BA = {].a,b.[ where a,b is Real: a < b};
reconsider BBA = BA as open quasi_basis Subset-Family of R^1
by TOPGEN_5:72;
A1: the topology of R^1 c= UniCl BBA by CANTOR_1:def 2;
A2: the carrier of FMT_R^1 = REAL by TOPMETR:17,FINTOPO7:def 15;
BA c= bool the carrier of FMT_R^1
proof
let x be object;
assume x in BA;
then ex a,b be Real st x = ].a,b.[ & a < b;
then reconsider x as Subset of REAL;
x in bool the carrier of FMT_R^1 by A2;
hence thesis;
end;
then reconsider BA as Subset-Family of FMT_R^1;
BA c= Family_open_set(FMT_R^1)
proof
let x be object;
assume
A3: x in BA;
then reconsider x as Subset of FMT_R^1;
consider a,b be Real such that
A4: x = ].a,b.[ and a < b by A3;
now
let y be Real;
assume
A5: y in x;
reconsider z = x as Subset of R^1 by FINTOPO7:def 15;
z is open by A4,JORDAN6:35;
hence ex r being Real st r > 0 & ].y - r, y + r.[ c= x by A5,FRECHET:8;
end;
then x is open by Th55;
then x in {O where O is open Subset of FMT_R^1: not contradiction};
hence thesis by FINTOPO7:def 11;
end;
then reconsider BA as open Subset-Family of FMT_R^1 by FINTOPO7:def 14;
now
let x be object;
assume x in Family_open_set(FMT_R^1);
then x in {O where O is open Subset of FMT_R^1: not contradiction}
by FINTOPO7:def 11;
then consider O be open Subset of FMT_R^1 such that
A6: x = O;
NTop2Top FMT_R^1 = R^1 by FINTOPO7:24;
then O is open Subset of R^1 by Lm9;
then O in the topology of R^1 by PRE_TOPC:def 2;
then consider Y be Subset-Family of R^1 such that
A7: Y c= BBA and
A8: O = union Y by A1,CANTOR_1:def 1;
reconsider Y as Subset-Family of FMT_R^1 by FINTOPO7:def 15;
Y c= BA by A7;
hence x in UniCl BA by A8,A6,CANTOR_1:def 1;
end;
then Family_open_set(FMT_R^1) c= UniCl BA;
hence thesis by FINTOPO7:def 13;
end;
theorem Th58:
r > 0 implies ].x - r , x + r.[ is a_neighborhood of x
proof
assume
A1: r > 0;
set S = ]. x - r, x + r.[,
BA = {].a,b.[ where a,b is Real: a < b};
now
x < x + r & x - r < x by A1,XREAL_1:29,44;
then x - r < x + r by XXREAL_0:2;
hence S in BA;
thus BA c= Family_open_set(FMT_R^1) by Th57,FINTOPO7:def 14;
end;
then S in Family_open_set(FMT_R^1);
then S in the set of all O where O is open Subset of FMT_R^1
by FINTOPO7:def 11;
then ex O be open Subset of FMT_R^1 st S = O;
then S in U_FMT x by A1,TOPREAL6:15,FINTOPO7:def 1;
hence thesis by FINTOPO7:def 5;
end;
theorem
for x being object holds x is Point of FMT_R^1 iff x is Point of RealSpace
by METRIC_1:def 13,TOPMETR:17,FINTOPO7:def 15;
theorem
x = y implies Ball(y,r) = ]. x - r , x + r .[ by FRECHET:7;
theorem Th61:
x = y & r > 0 implies Ball(y,r) is a_neighborhood of x
proof
assume that
A1: x = y and
A2: r > 0;
reconsider S = ]. x - r , x + r .[ as Subset of FMT_R^1
by TOPMETR:17,FINTOPO7:def 15;
S is a_neighborhood of x by A2,Th58;
hence thesis by A1,FRECHET:7;
end;
theorem
x = z implies Balls(z) is Subset-Family of FMT_R^1
by FINTOPO7:def 15,TOPMETR:def 6;
theorem
for SF being Subset-Family of FMT_R^1
st x = z & SF = Balls(z)
holds <. SF .] = U_FMT x
proof
let SF be Subset-Family of FMT_R^1;
assume that
A1: x = z and
A2: SF = Balls(z);
consider zy be Point of RealSpace such that
A3: z = zy and
A4: Balls(z) = { Ball(zy,1/n) where n is Nat: n <> 0} by FRECHET:def 1;
now
now
let a be object;
assume a in {x where x is Subset of FMT_R^1:
ex b be Element of SF st b c= x};
then consider y be Subset of FMT_R^1 such that
A5: a = y and
A6: ex b be Element of SF st b c= y;
consider b be Element of SF such that
A7: b c= y by A6;
b in Balls(z) by A2;
then consider n be Nat such that
A8: b = Ball(zy,1/n) and
A9: n <> 0 by A4;
reconsider r = 1 / n as Real;
now
now
0 <= n & n <> 0 by A9,NAT_1:2;
hence 0 < n by XXREAL_0:1;
thus 0 < 1;
end;
hence 0 / n < 1 / n by XREAL_1:74;
thus 0 / n = 0;
end;
then b is a_neighborhood of x by A1,A8,A3,Th61;
then b in U_FMT x by FINTOPO7:def 5;
hence a in U_FMT x by A5,A7,CARD_FIL:def 1;
end;
hence {x where x is Subset of FMT_R^1:
ex b be Element of SF st b c= x} c= U_FMT x;
now
let o be object;
assume
A10: o in U_FMT x;
then reconsider o9 = o as Subset of FMT_R^1;
reconsider Io9 = Int o9 as open a_neighborhood of x
by A10,FINTOPO7:def 5,Th14;
Io9 in U_FMT x by FINTOPO7:def 5;
then consider r be Real such that
A11: r > 0 and
A12: ]. x - r, x + r .[ c= Io9 by FINTOPO7:def 3,Th55;
consider n be Nat such that
A13: 1 / n < r and
A14: n > 0 by A11,FRECHET:36;
A15: ]. x - 1/n , x + 1/n .[ c= ]. x - r , x + r .[ by A13,INTEGRA6:2;
reconsider n1 = 1 / n as Real;
]. x - 1 / n , x + 1 / n .[ = Ball(zy,1 / n) by A1,A3,FRECHET:7;
then ]. x - 1/n , x + 1/n .[ in { Ball(zy,1/n) where
n is Nat: n <> 0} by A14;
then reconsider b = ]. x - 1/n , x + 1/n .[ as Element of SF by A2,A4;
b c= Io9 & Io9 c= o9 by A12,A15,Lm15;
then b c= o9;
hence o in {x where x is Subset of FMT_R^1:
ex b be Element of SF st b c= x};
end;
hence U_FMT x c= {x where x is Subset of FMT_R^1:
ex b be Element of SF st b c= x};
end;
hence thesis by CARDFIL2:14;
end;
definition
func gen_NS_R^1 -> Function of the carrier of
FMT_R^1,bool bool the carrier of FMT_R^1 means
:Def20:
for r being Real holds ex x being Point of TopSpaceMetr(RealSpace)
st x = r & it.r = Balls(x);
existence
proof
defpred P[object,object] means
ex x be Point of TopSpaceMetr(RealSpace) st x = $1 & $2 = Balls(x);
A1: for x be object st x in the carrier of FMT_R^1 ex y be object st
y in bool bool the carrier of FMT_R^1 & P[x,y]
proof
let x be object;
assume
A2: x in the carrier of FMT_R^1;
reconsider z = x as Element of TopSpaceMetr(RealSpace)
by A2,FINTOPO7:def 15,TOPMETR:def 6;
reconsider BZ = Balls(z) as Subset-Family of TopSpaceMetr(RealSpace);
reconsider y = Balls(z) as
Element of bool bool the carrier of FMT_R^1
by FINTOPO7:def 15,TOPMETR:def 6;
ex y be object st y in bool bool the carrier of FMT_R^1 & P[x,y]
proof
take y;
thus thesis;
end;
hence thesis;
end;
ex f be Function of the carrier of
FMT_R^1,bool bool the carrier of FMT_R^1 st
for x be object st x in the carrier of FMT_R^1 holds
P[x,f.x] from FUNCT_2:sch 1(A1);
then consider f be Function of the carrier of
FMT_R^1,bool bool the carrier of FMT_R^1 such that
A3: for x being object st x in the carrier of FMT_R^1 holds
P[x,f.x];
for r be Real ex y be Point of TopSpaceMetr(RealSpace) st r = y &
f.r = Balls(y) by A3,Th52,XREAL_0:def 1;
hence thesis;
end;
uniqueness
proof
let f1,f2 be Function of the carrier of FMT_R^1,
bool bool the carrier of FMT_R^1 such that
A4: for r being Real holds ex x being Point of TopSpaceMetr(RealSpace)
st x = r & f1.r = Balls(x) and
A5: for r being Real holds ex x being Point of TopSpaceMetr(RealSpace)
st x = r & f2.r = Balls(x);
now
dom f1 = the carrier of FMT_R^1 by FUNCT_2:def 1;
hence dom f1 = dom f2 by FUNCT_2:def 1;
hereby
let x be object;
assume x in dom f1;
then reconsider r = x as Real;
consider x1 be Point of TopSpaceMetr(RealSpace) such that
A6: r = x1 and
A7: f1.r = Balls(x1) by A4;
consider x2 be Point of TopSpaceMetr(RealSpace) such that
A8: r = x2 and
A9: f2.r = Balls(x2) by A5;
thus f1.x = f2.x by A6,A7,A8,A9;
end;
end;
hence f1 = f2 by FUNCT_1:2;
end;
end;
definition
func gen_R^1 -> non empty strict FMT_Space_Str equals
FMT_Space_Str(# the carrier of FMT_R^1, gen_NS_R^1 #);
coherence;
end;
theorem Th64:
the carrier of gen_R^1 = REAL by FINTOPO7:def 15,TOPMETR:17;
theorem Th65:
for x being Element of gen_R^1 holds
ex y being Point of TopSpaceMetr(RealSpace) st x = y &
U_FMT x = Balls(y)
proof
let x be Element of gen_R^1;
ex y be Point of TopSpaceMetr(RealSpace) st
y = x & (gen_NS_R^1).x = Balls(y) by Def20;
hence thesis by FINTOPO2:def 6;
end;
theorem
dom <. gen_R^1 .] = REAL by Th64,FUNCT_2:def 1;
theorem
gen_filter(gen_R^1) = FMT_R^1
proof
now
the carrier of FMT_R^1 = REAL by TOPMETR:17,FINTOPO7:def 15;
then dom the BNbd of FMT_R^1 = REAL by FUNCT_2:def 1;
hence dom <. gen_R^1 .] = dom the BNbd of FMT_R^1 by Th64,FUNCT_2:def 1;
hereby
let x be object;
assume x in dom <. gen_R^1 .];
then reconsider y = x as Element of the carrier of gen_R^1;
reconsider z = y as Element of FMT_R^1;
A1: (the BNbd of FMT_R^1). z = U_FMT z by FINTOPO2:def 6;
now
now
let o be object;
assume
A2: o in U_FMT z;
then reconsider S = o as Subset of FMT_R^1;
S is a_neighborhood of z by A2,FINTOPO7:def 5;
then consider O be open Subset of FMT_R^1 such that
A3: z in O and
A4: O c= S by FINTOPO7:15;
A5: NTop2Top FMT_R^1 = R^1 by FINTOPO7:24;
O is open Subset of R^1 by A5,Lm9;
then consider r be Real such that
A6: r > 0 and
A7: ]. z - r, z + r .[ c= O by A3,FRECHET:8;
consider n be Nat such that
A8: 1 / n < r and
A9: n > 0 by A6,FRECHET:36;
A10: ]. z - 1/n , z + 1/n .[ c= ]. z - r , z + r .[
by A8,INTEGRA6:2;
reconsider z9 = z as Point of TopSpaceMetr(RealSpace)
by TOPMETR:def 6,FINTOPO7:def 15;
consider zy be Point of RealSpace such that
A11: z9 = zy and
A12: Balls(z9) = { Ball(zy,1/n) where n is Nat: n <> 0}
by FRECHET:def 1;
A13: ]. z - 1 / n , z + 1 / n .[ = Ball(zy,1 / n) by A11,FRECHET:7;
consider py be Point of TopSpaceMetr(RealSpace) such that
A14: py = y and
A15: U_FMT y = Balls(py) by Th65;
]. z - 1/n , z + 1/n .[ in Balls(py) by A13,A9,A12,A14;
then reconsider b = ]. z - 1/n , z + 1/n .[ as
Element of U_FMT y by A15;
b c= S by A10,A7,A4;
hence o in <. (U_FMT y) .] by CARDFIL2:def 8;
end;
hence U_FMT z c= <. (U_FMT y) .];
now
let o be object;
assume
A16: o in <. (U_FMT y) .];
then reconsider O = o as Subset of gen_R^1;
consider b be Element of U_FMT y such that
A17: b c= O by A16,CARDFIL2:def 8;
reconsider z9 = z as Point of TopSpaceMetr(RealSpace)
by FINTOPO7:def 15,TOPMETR:def 6;
consider zy be Point of RealSpace such that
A18: z9 = zy and
A19: Balls(z9) = { Ball(zy,1/n) where n is Nat: n <> 0}
by FRECHET:def 1;
consider py be Point of TopSpaceMetr(RealSpace) such that
A20: py = y and
A21: U_FMT y = Balls(py) by Th65;
b in Balls(z9) by A21,A20;
then consider n be Nat such that
A22: b = Ball(zy,1/n) and
A23: n <> 0 by A19;
A24: ]. z - 1 / n , z + 1 / n .[ = Ball(zy,1 / n)
by A18,FRECHET:7;
A25: n > 0 by NAT_1:3,A23;
0 / n < 1 / n by A25,XREAL_1:74;
then Ball(zy,1/n) is a_neighborhood of z by A24,Th58;
then Ball(zy,1/n) in U_FMT z by FINTOPO7:def 5;
hence o in U_FMT z by A22,A17,CARD_FIL:def 1;
end;
hence <. (U_FMT y) .] c= U_FMT z;
end;
hence <. gen_R^1 .] . x = (the BNbd of FMT_R^1). x
by FINTOPO7:def 9,A1;
end;
end;
then FMT_Space_Str(# the carrier of gen_R^1,<. gen_R^1 .] #) = FMT_R^1
by FUNCT_1:2;
hence thesis by FINTOPO7:def 10;
end;
begin :: Transport Urysohn's lemma (URYSOHN3:20) from TopSpace to NTopSpace
theorem
for NT being non empty normal NTopSpace, A,B being closed Subset of NT st
A misses B holds ex F being Function of NT,FMT_R^1 st
F is continuous & for
x being Point of NT holds 0 <= F.x & F.x <= 1 & (x in A implies F.x = 0) &
(x in B implies F.x = 1)
proof
let NT be non empty normal NTopSpace;
let NA,NB be closed Subset of NT;
assume
A1: NA misses NB;
reconsider T = NTop2Top NT as non empty TopSpace;
reconsider T as non empty normal TopSpace;
reconsider A = NA, B = NB as closed Subset of T by Lm29;
consider F being Function of T,R^1 such that
A2: F is continuous and
A3: for x being Point of T holds 0 <= F.x & F.x <= 1 &
(x in A implies F.x = 0) & (x in B implies F.x = 1) by A1,URYSOHN3:20;
reconsider TTX = T as non empty TopSpace;
reconsider TTY = R^1 as non empty strict TopSpace;
reconsider G = F as continuous Function of TTX,TTY by A2;
A4: NT = Top2NTop T & FMT_R^1 = Top2NTop R^1 by FINTOPO7:25;
then reconsider F9 = Top2NTop G as Function of NT,FMT_R^1;
now
thus F9 is continuous by A4;
now
let x be Point of NT;
reconsider x9 = x as Point of T by FINTOPO7:def 16;
F9.x = F.x & 0 <= F.x9 by A3;
hence 0 <= F9.x;
F9.x = F.x & F.x9 <= 1 by A3;
hence F9.x <= 1;
end;
hence for x being Point of NT holds 0 <= F9.x & F9.x <= 1 &
(x in NA implies F9.x = 0) & (x in NB implies F9.x = 1) by A3;
end;
hence thesis;
end;