let n be Ordinal; for T being connected admissible TermOrder of n
for L being non trivial right_complementable almost_left_invertible associative commutative well-unital distributive add-associative right_zeroed doubleLoopStr
for f, p, g being Polynomial of n,L
for b, b' being bag of n st b < b',T & f reduces_to g,p,b,T holds
f . b' = g . b'
let T be connected admissible TermOrder of n; for L being non trivial right_complementable almost_left_invertible associative commutative well-unital distributive add-associative right_zeroed doubleLoopStr
for f, p, g being Polynomial of n,L
for b, b' being bag of n st b < b',T & f reduces_to g,p,b,T holds
f . b' = g . b'
let L be non trivial right_complementable almost_left_invertible associative commutative well-unital distributive add-associative right_zeroed doubleLoopStr ; for f, p, g being Polynomial of n,L
for b, b' being bag of n st b < b',T & f reduces_to g,p,b,T holds
f . b' = g . b'
let f, p, g be Polynomial of n,L; for b, b' being bag of n st b < b',T & f reduces_to g,p,b,T holds
f . b' = g . b'
let b, b' be bag of n; ( b < b',T & f reduces_to g,p,b,T implies f . b' = g . b' )
assume A1:
b < b',T
; ( not f reduces_to g,p,b,T or f . b' = g . b' )
assume
f reduces_to g,p,b,T
; f . b' = g . b'
then consider s being bag of n such that
A2:
s + (HT p,T) = b
and
A3:
g = f - (((f . b) / (HC p,T)) * (s *' p))
by Def5;
A6:
b' is Element of Bags n
by PRE_POLY:def 12;
A7: (((f . b) / (HC p,T)) * (s *' p)) . b' =
((f . b) / (HC p,T)) * ((s *' p) . b')
by POLYNOM7:def 10
.=
((f . b) / (HC p,T)) * (0. L)
by A6, A4, POLYNOM1:def 9
.=
0. L
by VECTSP_1:39
;
(f - (((f . b) / (HC p,T)) * (s *' p))) . b' =
(f + (- (((f . b) / (HC p,T)) * (s *' p)))) . b'
by POLYNOM1:def 23
.=
(f . b') + ((- (((f . b) / (HC p,T)) * (s *' p))) . b')
by POLYNOM1:def 21
.=
(f . b') + (- (0. L))
by A7, POLYNOM1:def 22
.=
(f . b') + (0. L)
by RLVECT_1:25
.=
f . b'
by RLVECT_1:def 7
;
hence
f . b' = g . b'
by A3; verum