let x, y, c be non pair set ; :: thesis: for s being State of (MajorityCirc x,y,c) holds Following s,2 is stable
set S = MajorityStr x,y,c;
reconsider xx = x, yy = y, cc = c as Vertex of (MajorityStr x,y,c) by Th72;
let s be State of (MajorityCirc x,y,c); :: thesis: Following s,2 is stable
set a1 = s . xx;
set a2 = s . yy;
set a3 = s . cc;
set ffs = Following s,2;
set fffs = Following (Following s,2);
A1: Following s,2 = Following (Following s) by Th15;
A2: y in InputVertices (MajorityStr x,y,c) by Th74;
then (Following s) . y = s . yy by CIRCUIT2:def 5;
then A3: (Following s,2) . y = s . yy by A1, A2, CIRCUIT2:def 5;
s . yy = s . y ;
then A4: (Following s,2) . [<*c,x*>,'&' ] = (s . cc) '&' (s . xx) by Lm3;
A5: x in InputVertices (MajorityStr x,y,c) by Th74;
then (Following s) . x = s . xx by CIRCUIT2:def 5;
then A6: (Following s,2) . x = s . xx by A1, A5, CIRCUIT2:def 5;
s . xx = s . x ;
then A7: (Following s,2) . [<*y,c*>,'&' ] = (s . yy) '&' (s . cc) by Lm3;
A8: c in InputVertices (MajorityStr x,y,c) by Th74;
then (Following s) . c = s . cc by CIRCUIT2:def 5;
then A9: (Following s,2) . c = s . cc by A1, A8, CIRCUIT2:def 5;
s . cc = s . c ;
then A10: (Following s,2) . [<*x,y*>,'&' ] = (s . xx) '&' (s . yy) by Lm3;
A11: (Following s,2) . (MajorityOutput x,y,c) = (((s . xx) '&' (s . yy)) 'or' ((s . yy) '&' (s . cc))) 'or' ((s . cc) '&' (s . xx)) by Lm3;
( dom (Following (Following s,2)) = the carrier of (MajorityStr x,y,c) & dom (Following s,2) = the carrier of (MajorityStr x,y,c) ) by CIRCUIT1:4;
hence Following s,2 = Following (Following s,2) by A12, FUNCT_1:9; :: according to CIRCUIT2:def 6 :: thesis: verum