now :: thesis: ( dom <.gen_R^1.] = dom the BNbd of FMT_R^1 & ( for x being object st x in dom <.gen_R^1.] holds
<.gen_R^1.] . x = the BNbd of FMT_R^1 . x ) )
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; :: thesis: for x being object st x in dom <.gen_R^1.] holds
<.gen_R^1.] . x = the BNbd of FMT_R^1 . x
hereby :: thesis: verum
let x be object ; :: thesis: ( x in dom <.gen_R^1.] implies <.gen_R^1.] . x = the BNbd of FMT_R^1 . x )
assume x in dom <.gen_R^1.] ; :: thesis: <.gen_R^1.] . x = the BNbd of FMT_R^1 . x
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 :: thesis: ( U_FMT z c= <.(U_FMT y).] & <.(U_FMT y).] c= U_FMT z )
now :: thesis: for o being object st o in U_FMT z holds
o in <.(U_FMT y).]
let o be object ; :: thesis: ( o in U_FMT z implies o in <.(U_FMT y).] )
assume A2: o in U_FMT z ; :: thesis: o in <.(U_FMT y).]
then reconsider S = o as Subset of FMT_R^1 ;
S is a_neighborhood of z by A2, FINTOPO7:def 5;
then consider O being 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 being Real such that
A6: r > 0 and
A7: ].(z - r),(z + r).[ c= O by A3, FRECHET:8;
consider n being 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 being 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 being 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; :: thesis: verum
end;
hence U_FMT z c= <.(U_FMT y).] ; :: thesis: <.(U_FMT y).] c= U_FMT z
now :: thesis: for o being object st o in <.(U_FMT y).] holds
o in U_FMT z
let o be object ; :: thesis: ( o in <.(U_FMT y).] implies o in U_FMT z )
assume A16: o in <.(U_FMT y).] ; :: thesis: o in U_FMT z
then reconsider O = o as Subset of gen_R^1 ;
consider b being 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 being 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 being 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 being 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; :: thesis: verum
end;
hence <.(U_FMT y).] c= U_FMT z ; :: thesis: verum
end;
hence <.gen_R^1.] . x = the BNbd of FMT_R^1 . x by FINTOPO7:def 9, A1; :: thesis: verum
end;
end;
then FMT_Space_Str(# the carrier of gen_R^1,<.gen_R^1.] #) = FMT_R^1 by FUNCT_1:2;
hence gen_filter gen_R^1 = FMT_R^1 by FINTOPO7:def 10; :: thesis: verum