let C be non empty compact non horizontal non vertical Subset of (TOP-REAL 2); :: thesis: for j, n being Nat st j <= len (Gauge C,n) holds
cell (Gauge C,n),(len (Gauge C,n)),j misses C
let j, n be Nat; :: thesis: ( j <= len (Gauge C,n) implies cell (Gauge C,n),(len (Gauge C,n)),j misses C )
set G = Gauge C,n;
A1: j in NAT by ORDINAL1:def 13;
assume A2: j <= len (Gauge C,n) ; :: thesis: cell (Gauge C,n),(len (Gauge C,n)),j misses C
A3: ( len (Gauge C,n) = (2 |^ n) + (1 + 2) & len (Gauge C,n) = width (Gauge C,n) ) by Def1;
assume (cell (Gauge C,n),(len (Gauge C,n)),j) /\ C <> {} ; :: according to XBOOLE_0:def 7 :: thesis: contradiction
then consider p being Point of (TOP-REAL 2) such that
A4: p in (cell (Gauge C,n),(len (Gauge C,n)),j) /\ C by SUBSET_1:10;
A5: ( p in cell (Gauge C,n),(len (Gauge C,n)),j & p in C ) by A4, XBOOLE_0:def 4;
4 <= len (Gauge C,n) by Th13;
then A6: 1 <= len (Gauge C,n) by XXREAL_0:2;
set W = W-bound C;
set S = S-bound C;
set E = E-bound C;
set N = N-bound C;
set EW = ((E-bound C) - (W-bound C)) / (2 |^ n);
[(len (Gauge C,n)),1] in Indices (Gauge C,n) by A3, A6, MATRIX_1:37;
then A7: (Gauge C,n) * (len (Gauge C,n)),1 = |[((W-bound C) + ((((E-bound C) - (W-bound C)) / (2 |^ n)) * ((len (Gauge C,n)) - 2))),((S-bound C) + ((((N-bound C) - (S-bound C)) / (2 |^ n)) * (1 - 2)))]| by Def1;
A8: 2 |^ n > 0 by NEWTON:102;
E-bound C > W-bound C by Th11;
then (E-bound C) - (W-bound C) > 0 by XREAL_1:52;
then A9: ((E-bound C) - (W-bound C)) / (2 |^ n) > 0 by A8, XREAL_1:141;
(((E-bound C) - (W-bound C)) / (2 |^ n)) * ((len (Gauge C,n)) - 2) = ((((E-bound C) - (W-bound C)) / (2 |^ n)) * (2 |^ n)) + ((((E-bound C) - (W-bound C)) / (2 |^ n)) * 1) by A3
.= ((E-bound C) - (W-bound C)) + (((E-bound C) - (W-bound C)) / (2 |^ n)) by A8, XCMPLX_1:88 ;
then ((Gauge C,n) * (len (Gauge C,n)),1) `1 = (E-bound C) + (((E-bound C) - (W-bound C)) / (2 |^ n)) by A7, EUCLID:56;
then A10: ((Gauge C,n) * (len (Gauge C,n)),1) `1 > E-bound C by A9, XREAL_1:31;
( j = 0 or j > 0 ) by NAT_1:3;
then A11: ( j = 0 or j >= 1 + 0 ) by NAT_1:9;
per cases ( j = 0 or j = len (Gauge C,n) or ( 1 <= j & j < len (Gauge C,n) ) ) by A2, A11, XXREAL_0:1;
suppose j = 0 ; :: thesis: contradiction
then cell (Gauge C,n),(len (Gauge C,n)),j = { |[r,s]| where r, s is Real : ( ((Gauge C,n) * (len (Gauge C,n)),1) `1 <= r & s <= ((Gauge C,n) * 1,1) `2 ) } by GOBRD11:27;
then consider r, s being Real such that
A12: p = |[r,s]| and
A13: ( ((Gauge C,n) * (len (Gauge C,n)),1) `1 <= r & s <= ((Gauge C,n) * 1,1) `2 ) by A5;
p `1 = r by A12, EUCLID:56;
then ( E-bound C < p `1 & p `1 <= E-bound C ) by A5, A10, A13, PSCOMP_1:71, XXREAL_0:2;
hence contradiction ; :: thesis: verum
end;
suppose j = len (Gauge C,n) ; :: thesis: contradiction
then cell (Gauge C,n),(len (Gauge C,n)),j = { |[r,s]| where r, s is Real : ( ((Gauge C,n) * (len (Gauge C,n)),1) `1 <= r & ((Gauge C,n) * 1,(width (Gauge C,n))) `2 <= s ) } by A3, GOBRD11:28;
then consider r, s being Real such that
A14: p = |[r,s]| and
A15: ( ((Gauge C,n) * (len (Gauge C,n)),1) `1 <= r & ((Gauge C,n) * 1,(width (Gauge C,n))) `2 <= s ) by A5;
p `1 = r by A14, EUCLID:56;
then ( E-bound C < p `1 & p `1 <= E-bound C ) by A5, A10, A15, PSCOMP_1:71, XXREAL_0:2;
hence contradiction ; :: thesis: verum
end;
suppose ( 1 <= j & j < len (Gauge C,n) ) ; :: thesis: contradiction
then cell (Gauge C,n),(len (Gauge C,n)),j = { |[r,s]| where r, s is Real : ( ((Gauge C,n) * (len (Gauge C,n)),1) `1 <= r & ((Gauge C,n) * 1,j) `2 <= s & s <= ((Gauge C,n) * 1,(j + 1)) `2 ) } by A1, A3, GOBRD11:29;
then consider r, s being Real such that
A16: p = |[r,s]| and
A17: ( ((Gauge C,n) * (len (Gauge C,n)),1) `1 <= r & ((Gauge C,n) * 1,j) `2 <= s & s <= ((Gauge C,n) * 1,(j + 1)) `2 ) by A5;
p `1 = r by A16, EUCLID:56;
then ( E-bound C < p `1 & p `1 <= E-bound C ) by A5, A10, A17, PSCOMP_1:71, XXREAL_0:2;
hence contradiction ; :: thesis: verum
end;
end;