A1:
( ( r1 = 0. R or s1 = 0. R ) & r2 <> 0. R & s2 = 1. R implies for z being Element of R holds
( z = 0. R iff z = (r1 * s1) / (gcd s1,r2,Amp) ) )
proof
set d =
(r1 * s1) / (gcd s1,r2,Amp);
assume that A2:
(
r1 = 0. R or
s1 = 0. R )
and A3:
r2 <> 0. R
and
s2 = 1. R
;
for z being Element of R holds
( z = 0. R iff z = (r1 * s1) / (gcd s1,r2,Amp) )
A4:
gcd s1,
r2,
Amp <> 0. R
by A3, Th34;
let z be
Element of
R;
( z = 0. R iff z = (r1 * s1) / (gcd s1,r2,Amp) )
A5:
r1 * s1 = 0. R
gcd s1,
r2,
Amp divides s1
by Def12;
then
gcd s1,
r2,
Amp divides r1 * s1
by Th7;
then
((r1 * s1) / (gcd s1,r2,Amp)) * (gcd s1,r2,Amp) = 0. R
by A5, A4, Def4;
hence
(
z = 0. R iff
z = (r1 * s1) / (gcd s1,r2,Amp) )
by A4, VECTSP_2:def 5;
verum
end;
A6:
( s2 <> 0. R & r2 = 1. R & r2 <> 0. R & s2 = 1. R implies for z being Element of R holds
( z = (r1 * s1) / (gcd r1,s2,Amp) iff z = (r1 * s1) / (gcd s1,r2,Amp) ) )
proof
assume that
s2 <> 0. R
and A7:
r2 = 1. R
and
r2 <> 0. R
and A8:
s2 = 1. R
;
for z being Element of R holds
( z = (r1 * s1) / (gcd r1,s2,Amp) iff z = (r1 * s1) / (gcd s1,r2,Amp) )
gcd s1,
r2,
Amp = 1. R
by A7, Th33;
hence
for
z being
Element of
R holds
(
z = (r1 * s1) / (gcd r1,s2,Amp) iff
z = (r1 * s1) / (gcd s1,r2,Amp) )
by A8, Th33;
verum
end;
A9:
( ( r1 = 0. R or s1 = 0. R ) & s2 <> 0. R & r2 = 1. R implies for z being Element of R holds
( z = 0. R iff z = (r1 * s1) / (gcd r1,s2,Amp) ) )
proof
set d =
(r1 * s1) / (gcd r1,s2,Amp);
assume that A10:
(
r1 = 0. R or
s1 = 0. R )
and A11:
s2 <> 0. R
and
r2 = 1. R
;
for z being Element of R holds
( z = 0. R iff z = (r1 * s1) / (gcd r1,s2,Amp) )
A12:
gcd r1,
s2,
Amp <> 0. R
by A11, Th34;
let z be
Element of
R;
( z = 0. R iff z = (r1 * s1) / (gcd r1,s2,Amp) )
A13:
r1 * s1 = 0. R
gcd r1,
s2,
Amp divides r1
by Def12;
then
gcd r1,
s2,
Amp divides r1 * s1
by Th7;
then
((r1 * s1) / (gcd r1,s2,Amp)) * (gcd r1,s2,Amp) = 0. R
by A13, A12, Def4;
hence
(
z = 0. R iff
z = (r1 * s1) / (gcd r1,s2,Amp) )
by A12, VECTSP_2:def 5;
verum
end;
A14:
( r2 = 1. R & s2 = 1. R & r2 <> 0. R & s2 = 1. R implies for z being Element of R holds
( z = r1 * s1 iff z = (r1 * s1) / (gcd s1,r2,Amp) ) )
A16:
( ( r1 = 0. R or s1 = 0. R ) & r2 = 1. R & s2 = 1. R implies for z being Element of R holds
( z = 0. R iff z = r1 * s1 ) )
proof
assume that A17:
(
r1 = 0. R or
s1 = 0. R )
and
r2 = 1. R
and
s2 = 1. R
;
for z being Element of R holds
( z = 0. R iff z = r1 * s1 )
hence
for
z being
Element of
R holds
(
z = 0. R iff
z = r1 * s1 )
;
verum
end;
( r2 = 1. R & s2 = 1. R & s2 <> 0. R & r2 = 1. R implies for z being Element of R holds
( z = r1 * s1 iff z = (r1 * s1) / (gcd r1,s2,Amp) ) )
hence
for b1 being Element of R holds
( ( ( r1 = 0. R or s1 = 0. R ) & r2 = 1. R & s2 = 1. R implies ( b1 = 0. R iff b1 = r1 * s1 ) ) & ( ( r1 = 0. R or s1 = 0. R ) & s2 <> 0. R & r2 = 1. R implies ( b1 = 0. R iff b1 = (r1 * s1) / (gcd r1,s2,Amp) ) ) & ( ( r1 = 0. R or s1 = 0. R ) & r2 <> 0. R & s2 = 1. R implies ( b1 = 0. R iff b1 = (r1 * s1) / (gcd s1,r2,Amp) ) ) & ( r2 = 1. R & s2 = 1. R & s2 <> 0. R & r2 = 1. R implies ( b1 = r1 * s1 iff b1 = (r1 * s1) / (gcd r1,s2,Amp) ) ) & ( r2 = 1. R & s2 = 1. R & r2 <> 0. R & s2 = 1. R implies ( b1 = r1 * s1 iff b1 = (r1 * s1) / (gcd s1,r2,Amp) ) ) & ( s2 <> 0. R & r2 = 1. R & r2 <> 0. R & s2 = 1. R implies ( b1 = (r1 * s1) / (gcd r1,s2,Amp) iff b1 = (r1 * s1) / (gcd s1,r2,Amp) ) ) )
by A16, A9, A1, A14, A6; verum