let Y be non empty set ; :: thesis:
let a, b, c be Element of Funcs (Y,BOOLEAN); :: thesis:
consider k3 being Function such that
A1: a = k3 and
A2: dom k3 = Y and
rng k3 c= BOOLEAN by FUNCT_2:def 2;
consider k4 being Function such that
A3: ((((a 'or' b) 'or' c) '&' ((a 'or' b) 'or' ('not' c))) '&' ((a 'or' ('not' b)) 'or' c)) '&' ((a 'or' ('not' b)) 'or' ('not' c)) = k4 and
A4: dom k4 = Y and
rng k4 c= BOOLEAN by FUNCT_2:def 2;
for x being Element of Y holds a . x = (((((a 'or' b) 'or' c) '&' ((a 'or' b) 'or' ('not' c))) '&' ((a 'or' ('not' b)) 'or' c)) '&' ((a 'or' ('not' b)) 'or' ('not' c))) . x

proof

let x be Element of Y; :: thesis:
(((((a 'or' b) 'or' c) '&' ((a 'or' b) 'or' ('not' c))) '&' ((a 'or' ('not' b)) 'or' c)) '&' ((a 'or' ('not' b)) 'or' ('not' c))) . x = ((((a 'or' b) 'or' (c '&' ('not' c))) '&' ((a 'or' ('not' b)) 'or' c)) '&' ((a 'or' ('not' b)) 'or' ('not' c))) . x by BVFUNC_1:11
.= ((((a 'or' b) 'or' (O_el Y)) '&' ((a 'or' ('not' b)) 'or' c)) '&' ((a 'or' ('not' b)) 'or' ('not' c))) . x by BVFUNC_4:5
.= (((a 'or' b) '&' ((a 'or' ('not' b)) 'or' c)) '&' ((a 'or' ('not' b)) 'or' ('not' c))) . x by BVFUNC_1:9
.= ((a 'or' b) '&' (((a 'or' ('not' b)) 'or' c) '&' ((a 'or' ('not' b)) 'or' ('not' c)))) . x by BVFUNC_1:4
.= ((a 'or' b) '&' ((a 'or' ('not' b)) 'or' (c '&' ('not' c)))) . x by BVFUNC_1:11
.= ((a 'or' b) '&' ((a 'or' ('not' b)) 'or' (O_el Y))) . x by BVFUNC_4:5
.= ((a 'or' b) '&' (a 'or' ('not' b))) . x by BVFUNC_1:9
.= (a 'or' (b '&' ('not' b))) . x by BVFUNC_1:11
.= (a 'or' (O_el Y)) . x by BVFUNC_4:5
.= a . x by BVFUNC_1:9 ;
hence a . x = (((((a 'or' b) 'or' c) '&' ((a 'or' b) 'or' ('not' c))) '&' ((a 'or' ('not' b)) 'or' c)) '&' ((a 'or' ('not' b)) 'or' ('not' c))) . x ; :: thesis:

end;

then for u being set st u in Y holds
k3 . u = k4 . u by A1, A3;
hence a = ((((a 'or' b) 'or' c) '&' ((a 'or' b) 'or' ('not' c))) '&' ((a 'or' ('not' b)) 'or' c)) '&' ((a 'or' ('not' b)) 'or' ('not' c)) by A1, A2, A3, A4, FUNCT_1:2; :: thesis: