let p, q, r be ZF-formula; :: thesis: for M being non empty set
for v being Function of VAR,M holds
( M,v |= ((p => q) '&' (q => r)) => (p => r) & M |= ((p => q) '&' (q => r)) => (p => r) )
let M be non empty set ; :: thesis: for v being Function of VAR,M holds
( M,v |= ((p => q) '&' (q => r)) => (p => r) & M |= ((p => q) '&' (q => r)) => (p => r) )
let v be Function of VAR,M; :: thesis: ( M,v |= ((p => q) '&' (q => r)) => (p => r) & M |= ((p => q) '&' (q => r)) => (p => r) )
now :: thesis: for v being Function of VAR,M holds M,v |= ((p => q) '&' (q => r)) => (p => r)
let v be Function of VAR,M; :: thesis: M,v |= ((p => q) '&' (q => r)) => (p => r)
now :: thesis: ( M,v |= (p => q) '&' (q => r) implies M,v |= p => r )
assume M,v |= (p => q) '&' (q => r) ; :: thesis: M,v |= p => r
then ( M,v |= p => q & M,v |= q => r ) by ZF_MODEL:15;
hence M,v |= p => r by Th102; :: thesis: verum
end;
hence M,v |= ((p => q) '&' (q => r)) => (p => r) by ZF_MODEL:18; :: thesis: verum
end;
hence ( M,v |= ((p => q) '&' (q => r)) => (p => r) & M |= ((p => q) '&' (q => r)) => (p => r) ) ; :: thesis: verum