let C, D be non empty set ; :: thesis: for B being Element of Fin C
for d being Element of D
for F, G being BinOp of D
for f being Function of C,D st F is commutative & F is associative & F is having_a_unity & F is having_an_inverseOp & G is_distributive_wrt F holds
G . (d,(F $$ (B,f))) = F $$ (B,(G [;] (d,f)))
let B be Element of Fin C; :: thesis: for d being Element of D
for F, G being BinOp of D
for f being Function of C,D st F is commutative & F is associative & F is having_a_unity & F is having_an_inverseOp & G is_distributive_wrt F holds
G . (d,(F $$ (B,f))) = F $$ (B,(G [;] (d,f)))
let d be Element of D; :: thesis: for F, G being BinOp of D
for f being Function of C,D st F is commutative & F is associative & F is having_a_unity & F is having_an_inverseOp & G is_distributive_wrt F holds
G . (d,(F $$ (B,f))) = F $$ (B,(G [;] (d,f)))
let F, G be BinOp of D; :: thesis: for f being Function of C,D st F is commutative & F is associative & F is having_a_unity & F is having_an_inverseOp & G is_distributive_wrt F holds
G . (d,(F $$ (B,f))) = F $$ (B,(G [;] (d,f)))
let f be Function of C,D; :: thesis: ( F is commutative & F is associative & F is having_a_unity & F is having_an_inverseOp & G is_distributive_wrt F implies G . (d,(F $$ (B,f))) = F $$ (B,(G [;] (d,f))) )
assume that
A1: ( F is commutative & F is associative & F is having_a_unity ) and
A2: F is having_an_inverseOp and
A3: G is_distributive_wrt F ; :: thesis: G . (d,(F $$ (B,f))) = F $$ (B,(G [;] (d,f)))
set e = the_unity_wrt F;
G . (d,(the_unity_wrt F)) = the_unity_wrt F by A1, A2, A3, FINSEQOP:66;
hence G . (d,(F $$ (B,f))) = F $$ (B,(G [;] (d,f))) by A1, A3, Th12; :: thesis: verum