let X be BCI-algebra; for x, y being Element of
for n being Element of NAT holds (0. X),(x \ y) to_power n = ((0. X),x to_power n) \ ((0. X),y to_power n)
let x, y be Element of ; for n being Element of NAT holds (0. X),(x \ y) to_power n = ((0. X),x to_power n) \ ((0. X),y to_power n)
let n be Element of NAT ; (0. X),(x \ y) to_power n = ((0. X),x to_power n) \ ((0. X),y to_power n)
defpred S1[ set ] means for m being Element of NAT st m = $1 & m <= n holds
(0. X),(x \ y) to_power m = ((0. X),x to_power m) \ ((0. X),y to_power m);
A1:
for k being Element of NAT st S1[k] holds
S1[k + 1]
proof
let k be
Element of
NAT ;
( S1[k] implies S1[k + 1] )
assume A2:
for
m being
Element of
NAT st
m = k &
m <= n holds
(0. X),
(x \ y) to_power m = ((0. X),x to_power m) \ ((0. X),y to_power m)
;
S1[k + 1]
let m be
Element of
NAT ;
( m = k + 1 & m <= n implies (0. X),(x \ y) to_power m = ((0. X),x to_power m) \ ((0. X),y to_power m) )
assume that A3:
m = k + 1
and A4:
m <= n
;
(0. X),(x \ y) to_power m = ((0. X),x to_power m) \ ((0. X),y to_power m)
k <= n
by A3, A4, NAT_1:13;
then
(0. X),
(x \ y) to_power k = ((0. X),x to_power k) \ ((0. X),y to_power k)
by A2;
then (0. X),
(x \ y) to_power (k + 1) =
(((0. X),x to_power k) \ ((0. X),y to_power k)) \ (x \ y)
by Th4
.=
(((0. X),x to_power k) \ (x \ y)) \ ((0. X),y to_power k)
by BCIALG_1:7
.=
(((x \ y) ` ),x to_power k) \ ((0. X),y to_power k)
by Th7
.=
(((x ` ) \ (y ` )),x to_power k) \ ((0. X),y to_power k)
by BCIALG_1:9
.=
(((x ` ),x to_power k) \ (y ` )) \ ((0. X),y to_power k)
by Th7
.=
(((x ` ),x to_power k) \ ((0. X),y to_power k)) \ (y ` )
by BCIALG_1:7
.=
((((0. X),x to_power k) \ x) \ ((0. X),y to_power k)) \ (y ` )
by Th7
;
then (0. X),
(x \ y) to_power (k + 1) =
(((0. X),x to_power (k + 1)) \ ((0. X),y to_power k)) \ (y ` )
by Th4
.=
(((0. X),x to_power (k + 1)) \ (y ` )) \ ((0. X),y to_power k)
by BCIALG_1:7
.=
(((y ` ) ` ),x to_power (k + 1)) \ ((0. X),y to_power k)
by Th7
.=
(((y ` ) ` ) \ ((0. X),y to_power k)),
x to_power (k + 1)
by Th7
.=
((((0. X),y to_power k) ` ) \ (y ` )),
x to_power (k + 1)
by BCIALG_1:7
.=
((((0. X),y to_power k) \ y) ` ),
x to_power (k + 1)
by BCIALG_1:9
.=
(((0. X),y to_power (k + 1)) ` ),
x to_power (k + 1)
by Th4
;
hence
(0. X),
(x \ y) to_power m = ((0. X),x to_power m) \ ((0. X),y to_power m)
by A3, Th7;
verum
end;
(0. X) ` = 0. X
by BCIALG_1:def 5;
then
(0. X),(x \ y) to_power 0 = (0. X) `
by Th1;
then
(0. X),(x \ y) to_power 0 = ((0. X),x to_power 0 ) \ (0. X)
by Th1;
then A5:
S1[ 0 ]
by Th1;
for n being Element of NAT holds S1[n]
from NAT_1:sch 1(A5, A1);
hence
(0. X),(x \ y) to_power n = ((0. X),x to_power n) \ ((0. X),y to_power n)
; verum