let D be non empty set ; for d1, d2 being Element of D
for F being BinOp of D
for u being UnOp of D st F is associative & F is having_a_unity & F is commutative & F is having_an_inverseOp & u = the_inverseOp_wrt F holds
( u . ((F * (id D),u) . d1,d2) = (F * u,(id D)) . d1,d2 & (F * (id D),u) . d1,d2 = u . ((F * u,(id D)) . d1,d2) )
let d1, d2 be Element of D; for F being BinOp of D
for u being UnOp of D st F is associative & F is having_a_unity & F is commutative & F is having_an_inverseOp & u = the_inverseOp_wrt F holds
( u . ((F * (id D),u) . d1,d2) = (F * u,(id D)) . d1,d2 & (F * (id D),u) . d1,d2 = u . ((F * u,(id D)) . d1,d2) )
let F be BinOp of D; for u being UnOp of D st F is associative & F is having_a_unity & F is commutative & F is having_an_inverseOp & u = the_inverseOp_wrt F holds
( u . ((F * (id D),u) . d1,d2) = (F * u,(id D)) . d1,d2 & (F * (id D),u) . d1,d2 = u . ((F * u,(id D)) . d1,d2) )
let u be UnOp of D; ( F is associative & F is having_a_unity & F is commutative & F is having_an_inverseOp & u = the_inverseOp_wrt F implies ( u . ((F * (id D),u) . d1,d2) = (F * u,(id D)) . d1,d2 & (F * (id D),u) . d1,d2 = u . ((F * u,(id D)) . d1,d2) ) )
assume that
A1:
( F is associative & F is having_a_unity )
and
A2:
F is commutative
and
A3:
( F is having_an_inverseOp & u = the_inverseOp_wrt F )
; ( u . ((F * (id D),u) . d1,d2) = (F * u,(id D)) . d1,d2 & (F * (id D),u) . d1,d2 = u . ((F * u,(id D)) . d1,d2) )
A4:
u is_distributive_wrt F
by A1, A2, A3, Th67;
thus u . ((F * (id D),u) . d1,d2) =
u . (F . d1,(u . d2))
by Th87
.=
F . (u . d1),(u . (u . d2))
by A4, BINOP_1:def 12
.=
F . (u . d1),d2
by A1, A3, Th66
.=
(F * u,(id D)) . d1,d2
by Th87
; (F * (id D),u) . d1,d2 = u . ((F * u,(id D)) . d1,d2)
hence
(F * (id D),u) . d1,d2 = u . ((F * u,(id D)) . d1,d2)
by A1, A3, Th66; verum