let Y be non empty set ; :: thesis: for G being Subset of (PARTITIONS Y)
for u, a being Element of Funcs (Y,BOOLEAN)
for PA being a_partition of Y st u is_independent_of PA,G holds
All ((a 'imp' u),PA,G) = (Ex (a,PA,G)) 'imp' u
let G be Subset of (PARTITIONS Y); :: thesis: for u, a being Element of Funcs (Y,BOOLEAN)
for PA being a_partition of Y st u is_independent_of PA,G holds
All ((a 'imp' u),PA,G) = (Ex (a,PA,G)) 'imp' u
let u, a be Element of Funcs (Y,BOOLEAN); :: thesis: for PA being a_partition of Y st u is_independent_of PA,G holds
All ((a 'imp' u),PA,G) = (Ex (a,PA,G)) 'imp' u
let PA be a_partition of Y; :: thesis: ( u is_independent_of PA,G implies All ((a 'imp' u),PA,G) = (Ex (a,PA,G)) 'imp' u )
assume u is_independent_of PA,G ; :: thesis: All ((a 'imp' u),PA,G) = (Ex (a,PA,G)) 'imp' u
then A1: u is_dependent_of CompF (PA,G) by Def8;
A2: (Ex (a,PA,G)) 'imp' u '<' All ((a 'imp' u),PA,G)
proof
let z be Element of Y; :: according to BVFUNC_1:def 12 :: thesis: ( not ((Ex (a,PA,G)) 'imp' u) . z = TRUE or (All ((a 'imp' u),PA,G)) . z = TRUE )
A3: z in EqClass (z,(CompF (PA,G))) by EQREL_1:def 6;
assume ((Ex (a,PA,G)) 'imp' u) . z = TRUE ; :: thesis: (All ((a 'imp' u),PA,G)) . z = TRUE
then A4: ('not' ((Ex (a,PA,G)) . z)) 'or' (u . z) = TRUE by BVFUNC_1:def 8;
A5: ( 'not' ((Ex (a,PA,G)) . z) = TRUE or 'not' ((Ex (a,PA,G)) . z) = FALSE ) by XBOOLEAN:def 3;
now
per cases ( u . z = TRUE or ( 'not' ((Ex (a,PA,G)) . z) = TRUE & u . z = FALSE ) ) by A4, A5, BINARITH:3, XBOOLEAN:def 3;
case A6: u . z = TRUE ; :: thesis: (All ((a 'imp' u),PA,G)) . z = TRUE
for x being Element of Y st x in EqClass (z,(CompF (PA,G))) holds
(a 'imp' u) . x = TRUE
proof
let x be Element of Y; :: thesis: ( x in EqClass (z,(CompF (PA,G))) implies (a 'imp' u) . x = TRUE )
assume x in EqClass (z,(CompF (PA,G))) ; :: thesis: (a 'imp' u) . x = TRUE
then ( (a 'imp' u) . x = ('not' (a . x)) 'or' (u . x) & u . x = u . z ) by A1, A3, BVFUNC_1:def 8, BVFUNC_1:def 15;
hence (a 'imp' u) . x = TRUE by A6, BINARITH:10; :: thesis: verum
end;
hence (All ((a 'imp' u),PA,G)) . z = TRUE by BVFUNC_1:def 16; :: thesis: verum
end;
case ( 'not' ((Ex (a,PA,G)) . z) = TRUE & u . z = FALSE ) ; :: thesis: (All ((a 'imp' u),PA,G)) . z = TRUE
then A7: (Ex (a,PA,G)) . z = FALSE by MARGREL1:11;
for x being Element of Y st x in EqClass (z,(CompF (PA,G))) holds
(a 'imp' u) . x = TRUE
proof
let x be Element of Y; :: thesis: ( x in EqClass (z,(CompF (PA,G))) implies (a 'imp' u) . x = TRUE )
assume x in EqClass (z,(CompF (PA,G))) ; :: thesis: (a 'imp' u) . x = TRUE
then a . x <> TRUE by A7, BVFUNC_1:def 17;
then ( (a 'imp' u) . x = ('not' (a . x)) 'or' (u . x) & a . x = FALSE ) by BVFUNC_1:def 8, XBOOLEAN:def 3;
then (a 'imp' u) . x = TRUE 'or' (u . x) by MARGREL1:11
.= TRUE by BINARITH:10 ;
hence (a 'imp' u) . x = TRUE ; :: thesis: verum
end;
hence (All ((a 'imp' u),PA,G)) . z = TRUE by BVFUNC_1:def 16; :: thesis: verum
end;
end;
end;
hence (All ((a 'imp' u),PA,G)) . z = TRUE ; :: thesis: verum
end;
All ((a 'imp' u),PA,G) '<' (Ex (a,PA,G)) 'imp' u
proof
let z be Element of Y; :: according to BVFUNC_1:def 12 :: thesis: ( not (All ((a 'imp' u),PA,G)) . z = TRUE or ((Ex (a,PA,G)) 'imp' u) . z = TRUE )
assume A8: (All ((a 'imp' u),PA,G)) . z = TRUE ; :: thesis: ((Ex (a,PA,G)) 'imp' u) . z = TRUE
A9: z in EqClass (z,(CompF (PA,G))) by EQREL_1:def 6;
A10: ((Ex (a,PA,G)) 'imp' u) . z = ('not' ((Ex (a,PA,G)) . z)) 'or' (u . z) by BVFUNC_1:def 8;
per cases ( for x being Element of Y st x in EqClass (z,(CompF (PA,G))) holds
u . x = TRUE or ( ex x being Element of Y st
( x in EqClass (z,(CompF (PA,G))) & not u . x = TRUE ) & ex x being Element of Y st
( x in EqClass (z,(CompF (PA,G))) & a . x = TRUE ) ) or ( ex x being Element of Y st
( x in EqClass (z,(CompF (PA,G))) & not u . x = TRUE ) & ( for x being Element of Y holds
( not x in EqClass (z,(CompF (PA,G))) or not a . x = TRUE ) ) ) ) ;
suppose for x being Element of Y st x in EqClass (z,(CompF (PA,G))) holds
u . x = TRUE ; :: thesis: ((Ex (a,PA,G)) 'imp' u) . z = TRUE
then ((Ex (a,PA,G)) 'imp' u) . z = ('not' ((Ex (a,PA,G)) . z)) 'or' TRUE by A9, A10
.= TRUE by BINARITH:10 ;
hence ((Ex (a,PA,G)) 'imp' u) . z = TRUE ; :: thesis: verum
end;
suppose A11: ( ex x being Element of Y st
( x in EqClass (z,(CompF (PA,G))) & not u . x = TRUE ) & ex x being Element of Y st
( x in EqClass (z,(CompF (PA,G))) & a . x = TRUE ) ) ; :: thesis: ((Ex (a,PA,G)) 'imp' u) . z = TRUE
then consider x1 being Element of Y such that
A12: x1 in EqClass (z,(CompF (PA,G))) and
A13: u . x1 <> TRUE ;
consider x2 being Element of Y such that
A14: x2 in EqClass (z,(CompF (PA,G))) and
A15: a . x2 = TRUE by A11;
A16: u . x1 = u . x2 by A1, A12, A14, BVFUNC_1:def 15;
(a 'imp' u) . x2 = ('not' (a . x2)) 'or' (u . x2) by BVFUNC_1:def 8
.= ('not' TRUE) 'or' FALSE by A13, A15, A16, XBOOLEAN:def 3
.= FALSE 'or' FALSE by MARGREL1:11
.= FALSE ;
hence ((Ex (a,PA,G)) 'imp' u) . z = TRUE by A8, A14, BVFUNC_1:def 16; :: thesis: verum
end;
suppose ( ex x being Element of Y st
( x in EqClass (z,(CompF (PA,G))) & not u . x = TRUE ) & ( for x being Element of Y holds
( not x in EqClass (z,(CompF (PA,G))) or not a . x = TRUE ) ) ) ; :: thesis: ((Ex (a,PA,G)) 'imp' u) . z = TRUE
then ((Ex (a,PA,G)) 'imp' u) . z = ('not' FALSE) 'or' (u . z) by A10, BVFUNC_1:def 17
.= TRUE 'or' (u . z) by MARGREL1:11
.= TRUE by BINARITH:10 ;
hence ((Ex (a,PA,G)) 'imp' u) . z = TRUE ; :: thesis: verum
end;
end;
end;
hence All ((a 'imp' u),PA,G) = (Ex (a,PA,G)) 'imp' u by A2, BVFUNC_1:15; :: thesis: verum