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4ed13..
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Param
ordinal
ordinal
:
ι
→
ο
Definition
or
or
:=
λ x0 x1 : ο .
∀ x2 : ο .
(
x0
⟶
x2
)
⟶
(
x1
⟶
x2
)
⟶
x2
Known
ordinal_trichotomy_or
ordinal_trichotomy_or
:
∀ x0 x1 .
ordinal
x0
⟶
ordinal
x1
⟶
or
(
or
(
x0
∈
x1
)
(
x0
=
x1
)
)
(
x1
∈
x0
)
Theorem
ordinal_trichotomy_or_impred
ordinal_trichotomy_or_impred
:
∀ x0 x1 .
ordinal
x0
⟶
ordinal
x1
⟶
∀ x2 : ο .
(
x0
∈
x1
⟶
x2
)
⟶
(
x0
=
x1
⟶
x2
)
⟶
(
x1
∈
x0
⟶
x2
)
⟶
x2
(proof)
Param
SNo
SNo
:
ι
→
ο
Param
SNoLt
SNoLt
:
ι
→
ι
→
ο
Param
SNoL
SNoL
:
ι
→
ι
Param
SNoR
SNoR
:
ι
→
ι
Param
SNoLev
SNoLev
:
ι
→
ι
Param
binintersect
binintersect
:
ι
→
ι
→
ι
Param
SNoEq_
SNoEq_
:
ι
→
ι
→
ι
→
ο
Param
nIn
nIn
:
ι
→
ι
→
ο
Known
SNoLtE
SNoLtE
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
SNoLt
x0
x1
⟶
∀ x2 : ο .
(
∀ x3 .
SNo
x3
⟶
SNoLev
x3
∈
binintersect
(
SNoLev
x0
)
(
SNoLev
x1
)
⟶
SNoEq_
(
SNoLev
x3
)
x3
x0
⟶
SNoEq_
(
SNoLev
x3
)
x3
x1
⟶
SNoLt
x0
x3
⟶
SNoLt
x3
x1
⟶
nIn
(
SNoLev
x3
)
x0
⟶
SNoLev
x3
∈
x1
⟶
x2
)
⟶
(
SNoLev
x0
∈
SNoLev
x1
⟶
SNoEq_
(
SNoLev
x0
)
x0
x1
⟶
SNoLev
x0
∈
x1
⟶
x2
)
⟶
(
SNoLev
x1
∈
SNoLev
x0
⟶
SNoEq_
(
SNoLev
x1
)
x0
x1
⟶
nIn
(
SNoLev
x1
)
x0
⟶
x2
)
⟶
x2
Definition
and
and
:=
λ x0 x1 : ο .
∀ x2 : ο .
(
x0
⟶
x1
⟶
x2
)
⟶
x2
Known
binintersectE
binintersectE
:
∀ x0 x1 x2 .
x2
∈
binintersect
x0
x1
⟶
and
(
x2
∈
x0
)
(
x2
∈
x1
)
Known
SNoL_I
SNoL_I
:
∀ x0 .
SNo
x0
⟶
∀ x1 .
SNo
x1
⟶
SNoLev
x1
∈
SNoLev
x0
⟶
SNoLt
x1
x0
⟶
x1
∈
SNoL
x0
Known
SNoR_I
SNoR_I
:
∀ x0 .
SNo
x0
⟶
∀ x1 .
SNo
x1
⟶
SNoLev
x1
∈
SNoLev
x0
⟶
SNoLt
x0
x1
⟶
x1
∈
SNoR
x0
Theorem
SNoLt_SNoL_or_SNoR_impred
SNoLt_SNoL_or_SNoR_impred
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
SNoLt
x0
x1
⟶
∀ x2 : ο .
(
∀ x3 .
x3
∈
SNoL
x1
⟶
x3
∈
SNoR
x0
⟶
x2
)
⟶
(
x0
∈
SNoL
x1
⟶
x2
)
⟶
(
x1
∈
SNoR
x0
⟶
x2
)
⟶
x2
(proof)
Known
SNoLt_trichotomy_or_impred
SNoLt_trichotomy_or_impred
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
∀ x2 : ο .
(
SNoLt
x0
x1
⟶
x2
)
⟶
(
x0
=
x1
⟶
x2
)
⟶
(
SNoLt
x1
x0
⟶
x2
)
⟶
x2
Theorem
SNoL_or_SNoR_impred
SNoL_or_SNoR_impred
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
∀ x2 : ο .
(
x0
=
x1
⟶
x2
)
⟶
(
∀ x3 .
x3
∈
SNoL
x1
⟶
x3
∈
SNoR
x0
⟶
x2
)
⟶
(
x0
∈
SNoL
x1
⟶
x2
)
⟶
(
x1
∈
SNoR
x0
⟶
x2
)
⟶
(
∀ x3 .
x3
∈
SNoR
x1
⟶
x3
∈
SNoL
x0
⟶
x2
)
⟶
(
x0
∈
SNoR
x1
⟶
x2
)
⟶
(
x1
∈
SNoL
x0
⟶
x2
)
⟶
x2
(proof)
Param
add_SNo
add_SNo
:
ι
→
ι
→
ι
Param
minus_SNo
minus_SNo
:
ι
→
ι
Known
add_SNo_assoc
add_SNo_assoc
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
add_SNo
x0
(
add_SNo
x1
x2
)
=
add_SNo
(
add_SNo
x0
x1
)
x2
Known
SNo_minus_SNo
SNo_minus_SNo
:
∀ x0 .
SNo
x0
⟶
SNo
(
minus_SNo
x0
)
Known
add_SNo_minus_SNo_rinv
add_SNo_minus_SNo_rinv
:
∀ x0 .
SNo
x0
⟶
add_SNo
x0
(
minus_SNo
x0
)
=
0
Known
add_SNo_0R
add_SNo_0R
:
∀ x0 .
SNo
x0
⟶
add_SNo
x0
0
=
x0
Theorem
add_SNo_minus_R2
add_SNo_minus_R2
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
add_SNo
(
add_SNo
x0
x1
)
(
minus_SNo
x1
)
=
x0
(proof)
Known
add_SNo_Lt1
add_SNo_Lt1
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNoLt
x0
x2
⟶
SNoLt
(
add_SNo
x0
x1
)
(
add_SNo
x2
x1
)
Known
SNo_add_SNo
SNo_add_SNo
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
SNo
(
add_SNo
x0
x1
)
Theorem
add_SNo_Lt1_cancel
add_SNo_Lt1_cancel
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNoLt
(
add_SNo
x0
x1
)
(
add_SNo
x2
x1
)
⟶
SNoLt
x0
x2
(proof)
Theorem
add_SNo_assoc_4
add_SNo_assoc_4
:
∀ x0 x1 x2 x3 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
add_SNo
x0
(
add_SNo
x1
(
add_SNo
x2
x3
)
)
=
add_SNo
(
add_SNo
x0
(
add_SNo
x1
x2
)
)
x3
(proof)
Known
add_SNo_com
add_SNo_com
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
add_SNo
x0
x1
=
add_SNo
x1
x0
Theorem
add_SNo_com_3_0_1
add_SNo_com_3_0_1
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
add_SNo
x0
(
add_SNo
x1
x2
)
=
add_SNo
x1
(
add_SNo
x0
x2
)
(proof)
Theorem
add_SNo_com_4_inner_flat
add_SNo_com_4_inner_flat
:
∀ x0 x1 x2 x3 .
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
add_SNo
x0
(
add_SNo
x1
(
add_SNo
x2
x3
)
)
=
add_SNo
x0
(
add_SNo
x2
(
add_SNo
x1
x3
)
)
(proof)
Theorem
add_SNo_com_3b_1_2
add_SNo_com_3b_1_2
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
add_SNo
(
add_SNo
x0
x1
)
x2
=
add_SNo
(
add_SNo
x0
x2
)
x1
(proof)
Theorem
add_SNo_com_4_inner_mid
add_SNo_com_4_inner_mid
:
∀ x0 x1 x2 x3 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
add_SNo
(
add_SNo
x0
x1
)
(
add_SNo
x2
x3
)
=
add_SNo
(
add_SNo
x0
x2
)
(
add_SNo
x1
x3
)
(proof)
Theorem
add_SNo_rotate_3_1
add_SNo_rotate_3_1
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
add_SNo
x0
(
add_SNo
x1
x2
)
=
add_SNo
x2
(
add_SNo
x0
x1
)
(proof)
Known
add_SNo_minus_SNo_linv
add_SNo_minus_SNo_linv
:
∀ x0 .
SNo
x0
⟶
add_SNo
(
minus_SNo
x0
)
x0
=
0
Known
add_SNo_0L
add_SNo_0L
:
∀ x0 .
SNo
x0
⟶
add_SNo
0
x0
=
x0
Theorem
add_SNo_minus_L2
add_SNo_minus_L2
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
add_SNo
(
minus_SNo
x0
)
(
add_SNo
x0
x1
)
=
x1
(proof)
Theorem
add_SNo_minus_SNo_prop2
add_SNo_minus_SNo_prop2
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
add_SNo
x0
(
add_SNo
(
minus_SNo
x0
)
x1
)
=
x1
(proof)
Theorem
add_SNo_minus_SNo_prop3
add_SNo_minus_SNo_prop3
:
∀ x0 x1 x2 x3 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
add_SNo
(
add_SNo
x0
(
add_SNo
x1
x2
)
)
(
add_SNo
(
minus_SNo
x2
)
x3
)
=
add_SNo
x0
(
add_SNo
x1
x3
)
(proof)
Theorem
add_SNo_minus_SNo_prop4
add_SNo_minus_SNo_prop4
:
∀ x0 x1 x2 x3 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
add_SNo
(
add_SNo
x0
(
add_SNo
x1
x2
)
)
(
add_SNo
x3
(
minus_SNo
x2
)
)
=
add_SNo
x0
(
add_SNo
x1
x3
)
(proof)
Known
minus_SNo_invol
minus_SNo_invol
:
∀ x0 .
SNo
x0
⟶
minus_SNo
(
minus_SNo
x0
)
=
x0
Theorem
add_SNo_minus_SNo_prop5
add_SNo_minus_SNo_prop5
:
∀ x0 x1 x2 x3 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
add_SNo
(
add_SNo
x0
(
add_SNo
x1
(
minus_SNo
x2
)
)
)
(
add_SNo
x2
x3
)
=
add_SNo
x0
(
add_SNo
x1
x3
)
(proof)
Theorem
add_SNo_minus_Lt1
add_SNo_minus_Lt1
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNoLt
(
add_SNo
x0
(
minus_SNo
x1
)
)
x2
⟶
SNoLt
x0
(
add_SNo
x2
x1
)
(proof)
Theorem
add_SNo_minus_Lt2
add_SNo_minus_Lt2
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNoLt
x2
(
add_SNo
x0
(
minus_SNo
x1
)
)
⟶
SNoLt
(
add_SNo
x2
x1
)
x0
(proof)
Known
add_SNo_Lt3
add_SNo_Lt3
:
∀ x0 x1 x2 x3 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
SNoLt
x0
x2
⟶
SNoLt
x1
x3
⟶
SNoLt
(
add_SNo
x0
x1
)
(
add_SNo
x2
x3
)
Theorem
add_SNo_Lt_subprop2
add_SNo_Lt_subprop2
:
∀ x0 x1 x2 x3 x4 x5 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
SNo
x4
⟶
SNo
x5
⟶
SNoLt
(
add_SNo
x0
x4
)
(
add_SNo
x2
x5
)
⟶
SNoLt
(
add_SNo
x1
x5
)
(
add_SNo
x3
x4
)
⟶
SNoLt
(
add_SNo
x0
x1
)
(
add_SNo
x2
x3
)
(proof)
Known
SNoLt_tra
SNoLt_tra
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNoLt
x0
x1
⟶
SNoLt
x1
x2
⟶
SNoLt
x0
x2
Known
add_SNo_Lt2
add_SNo_Lt2
:
∀ x0 x1 x2 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNoLt
x1
x2
⟶
SNoLt
(
add_SNo
x0
x1
)
(
add_SNo
x0
x2
)
Theorem
add_SNo_Lt_subprop3a
add_SNo_Lt_subprop3a
:
∀ x0 x1 x2 x3 x4 x5 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
SNo
x4
⟶
SNo
x5
⟶
SNoLt
(
add_SNo
x0
x2
)
(
add_SNo
x3
x5
)
⟶
SNoLt
(
add_SNo
x1
x5
)
x4
⟶
SNoLt
(
add_SNo
x0
(
add_SNo
x1
x2
)
)
(
add_SNo
x3
x4
)
(proof)
Known
SNo_0
SNo_0
:
SNo
0
Theorem
add_SNo_Lt_subprop3b
add_SNo_Lt_subprop3b
:
∀ x0 x1 x2 x3 x4 x5 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
SNo
x4
⟶
SNo
x5
⟶
SNoLt
(
add_SNo
x0
x5
)
(
add_SNo
x2
x4
)
⟶
SNoLt
x1
(
add_SNo
x5
x3
)
⟶
SNoLt
(
add_SNo
x0
x1
)
(
add_SNo
x2
(
add_SNo
x3
x4
)
)
(proof)
Theorem
add_SNo_Lt_subprop3c
add_SNo_Lt_subprop3c
:
∀ x0 x1 x2 x3 x4 x5 x6 x7 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
SNo
x4
⟶
SNo
x5
⟶
SNo
x6
⟶
SNo
x7
⟶
SNoLt
(
add_SNo
x0
x5
)
(
add_SNo
x6
x7
)
⟶
SNoLt
(
add_SNo
x1
x7
)
x4
⟶
SNoLt
(
add_SNo
x6
x2
)
(
add_SNo
x3
x5
)
⟶
SNoLt
(
add_SNo
x0
(
add_SNo
x1
x2
)
)
(
add_SNo
x3
x4
)
(proof)
Theorem
add_SNo_Lt_subprop3d
add_SNo_Lt_subprop3d
:
∀ x0 x1 x2 x3 x4 x5 x6 x7 .
SNo
x0
⟶
SNo
x1
⟶
SNo
x2
⟶
SNo
x3
⟶
SNo
x4
⟶
SNo
x5
⟶
SNo
x6
⟶
SNo
x7
⟶
SNoLt
(
add_SNo
x0
x5
)
(
add_SNo
x6
x4
)
⟶
SNoLt
x1
(
add_SNo
x7
x3
)
⟶
SNoLt
(
add_SNo
x6
x7
)
(
add_SNo
x2
x5
)
⟶
SNoLt
(
add_SNo
x0
x1
)
(
add_SNo
x2
(
add_SNo
x3
x4
)
)
(proof)
Param
mul_SNo
mul_SNo
:
ι
→
ι
→
ι
Param
SNoCut
SNoCut
:
ι
→
ι
→
ι
Param
binunion
binunion
:
ι
→
ι
→
ι
Param
lam
Sigma
:
ι
→
(
ι
→
ι
) →
ι
Definition
setprod
setprod
:=
λ x0 x1 .
lam
x0
(
λ x2 .
x1
)
Param
ap
ap
:
ι
→
ι
→
ι
Param
ordsucc
ordsucc
:
ι
→
ι
Known
binunionE
binunionE
:
∀ x0 x1 x2 .
x2
∈
binunion
x0
x1
⟶
or
(
x2
∈
x0
)
(
x2
∈
x1
)
Known
ReplE_impred
ReplE_impred
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
prim5
x0
x1
⟶
∀ x3 : ο .
(
∀ x4 .
x4
∈
x0
⟶
x2
=
x1
x4
⟶
x3
)
⟶
x3
Known
ap0_Sigma
ap0_Sigma
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
lam
x0
x1
⟶
ap
x2
0
∈
x0
Known
ap1_Sigma
ap1_Sigma
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
lam
x0
x1
⟶
ap
x2
1
∈
x1
(
ap
x2
0
)
Known
binunionI1
binunionI1
:
∀ x0 x1 x2 .
x2
∈
x0
⟶
x2
∈
binunion
x0
x1
Param
If_i
If_i
:
ο
→
ι
→
ι
→
ι
Known
tuple_2_0_eq
tuple_2_0_eq
:
∀ x0 x1 .
ap
(
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
)
0
=
x0
Known
tuple_2_1_eq
tuple_2_1_eq
:
∀ x0 x1 .
ap
(
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
)
1
=
x1
Known
ReplI
ReplI
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
x0
⟶
x1
x2
∈
prim5
x0
x1
Known
tuple_2_setprod
tuple_2_setprod
:
∀ x0 x1 x2 .
x2
∈
x0
⟶
∀ x3 .
x3
∈
x1
⟶
lam
2
(
λ x4 .
If_i
(
x4
=
0
)
x2
x3
)
∈
setprod
x0
x1
Known
binunionI2
binunionI2
:
∀ x0 x1 x2 .
x2
∈
x1
⟶
x2
∈
binunion
x0
x1
Known
mul_SNo_eq
mul_SNo_eq
:
∀ x0 .
SNo
x0
⟶
∀ x1 .
SNo
x1
⟶
mul_SNo
x0
x1
=
SNoCut
(
binunion
{
add_SNo
(
mul_SNo
(
ap
x3
0
)
x1
)
(
add_SNo
(
mul_SNo
x0
(
ap
x3
1
)
)
(
minus_SNo
(
mul_SNo
(
ap
x3
0
)
(
ap
x3
1
)
)
)
)
|x3 ∈
setprod
(
SNoL
x0
)
(
SNoL
x1
)
}
{
add_SNo
(
mul_SNo
(
ap
x3
0
)
x1
)
(
add_SNo
(
mul_SNo
x0
(
ap
x3
1
)
)
(
minus_SNo
(
mul_SNo
(
ap
x3
0
)
(
ap
x3
1
)
)
)
)
|x3 ∈
setprod
(
SNoR
x0
)
(
SNoR
x1
)
}
)
(
binunion
{
add_SNo
(
mul_SNo
(
ap
x3
0
)
x1
)
(
add_SNo
(
mul_SNo
x0
(
ap
x3
1
)
)
(
minus_SNo
(
mul_SNo
(
ap
x3
0
)
(
ap
x3
1
)
)
)
)
|x3 ∈
setprod
(
SNoL
x0
)
(
SNoR
x1
)
}
{
add_SNo
(
mul_SNo
(
ap
x3
0
)
x1
)
(
add_SNo
(
mul_SNo
x0
(
ap
x3
1
)
)
(
minus_SNo
(
mul_SNo
(
ap
x3
0
)
(
ap
x3
1
)
)
)
)
|x3 ∈
setprod
(
SNoR
x0
)
(
SNoL
x1
)
}
)
Theorem
mul_SNo_eq_2
mul_SNo_eq_2
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
∀ x2 : ο .
(
∀ x3 x4 .
(
∀ x5 .
x5
∈
x3
⟶
∀ x6 : ο .
(
∀ x7 .
x7
∈
SNoL
x0
⟶
∀ x8 .
x8
∈
SNoL
x1
⟶
x5
=
add_SNo
(
mul_SNo
x7
x1
)
(
add_SNo
(
mul_SNo
x0
x8
)
(
minus_SNo
(
mul_SNo
x7
x8
)
)
)
⟶
x6
)
⟶
(
∀ x7 .
x7
∈
SNoR
x0
⟶
∀ x8 .
x8
∈
SNoR
x1
⟶
x5
=
add_SNo
(
mul_SNo
x7
x1
)
(
add_SNo
(
mul_SNo
x0
x8
)
(
minus_SNo
(
mul_SNo
x7
x8
)
)
)
⟶
x6
)
⟶
x6
)
⟶
(
∀ x5 .
x5
∈
SNoL
x0
⟶
∀ x6 .
x6
∈
SNoL
x1
⟶
add_SNo
(
mul_SNo
x5
x1
)
(
add_SNo
(
mul_SNo
x0
x6
)
(
minus_SNo
(
mul_SNo
x5
x6
)
)
)
∈
x3
)
⟶
(
∀ x5 .
x5
∈
SNoR
x0
⟶
∀ x6 .
x6
∈
SNoR
x1
⟶
add_SNo
(
mul_SNo
x5
x1
)
(
add_SNo
(
mul_SNo
x0
x6
)
(
minus_SNo
(
mul_SNo
x5
x6
)
)
)
∈
x3
)
⟶
(
∀ x5 .
x5
∈
x4
⟶
∀ x6 : ο .
(
∀ x7 .
x7
∈
SNoL
x0
⟶
∀ x8 .
x8
∈
SNoR
x1
⟶
x5
=
add_SNo
(
mul_SNo
x7
x1
)
(
add_SNo
(
mul_SNo
x0
x8
)
(
minus_SNo
(
mul_SNo
x7
x8
)
)
)
⟶
x6
)
⟶
(
∀ x7 .
x7
∈
SNoR
x0
⟶
∀ x8 .
x8
∈
SNoL
x1
⟶
x5
=
add_SNo
(
mul_SNo
x7
x1
)
(
add_SNo
(
mul_SNo
x0
x8
)
(
minus_SNo
(
mul_SNo
x7
x8
)
)
)
⟶
x6
)
⟶
x6
)
⟶
(
∀ x5 .
x5
∈
SNoL
x0
⟶
∀ x6 .
x6
∈
SNoR
x1
⟶
add_SNo
(
mul_SNo
x5
x1
)
(
add_SNo
(
mul_SNo
x0
x6
)
(
minus_SNo
(
mul_SNo
x5
x6
)
)
)
∈
x4
)
⟶
(
∀ x5 .
x5
∈
SNoR
x0
⟶
∀ x6 .
x6
∈
SNoL
x1
⟶
add_SNo
(
mul_SNo
x5
x1
)
(
add_SNo
(
mul_SNo
x0
x6
)
(
minus_SNo
(
mul_SNo
x5
x6
)
)
)
∈
x4
)
⟶
mul_SNo
x0
x1
=
SNoCut
x3
x4
⟶
x2
)
⟶
x2
(proof)
Param
SNoS_
SNoS_
:
ι
→
ι
Known
SNoLev_ind
SNoLev_ind
:
∀ x0 :
ι → ο
.
(
∀ x1 .
SNo
x1
⟶
(
∀ x2 .
x2
∈
SNoS_
(
SNoLev
x1
)
⟶
x0
x2
)
⟶
x0
x1
)
⟶
∀ x1 .
SNo
x1
⟶
x0
x1
Definition
SNoCutP
SNoCutP
:=
λ x0 x1 .
and
(
and
(
∀ x2 .
x2
∈
x0
⟶
SNo
x2
)
(
∀ x2 .
x2
∈
x1
⟶
SNo
x2
)
)
(
∀ x2 .
x2
∈
x0
⟶
∀ x3 .
x3
∈
x1
⟶
SNoLt
x2
x3
)
Known
SNoL_E
SNoL_E
:
∀ x0 .
SNo
x0
⟶
∀ x1 .
x1
∈
SNoL
x0
⟶
∀ x2 : ο .
(
SNo
x1
⟶
SNoLev
x1
∈
SNoLev
x0
⟶
SNoLt
x1
x0
⟶
x2
)
⟶
x2
Known
SNoCutP_SNoCut_L
SNoCutP_SNoCut_L
:
∀ x0 x1 .
SNoCutP
x0
x1
⟶
∀ x2 .
x2
∈
x0
⟶
SNoLt
x2
(
SNoCut
x0
x1
)
Known
SNoR_E
SNoR_E
:
∀ x0 .
SNo
x0
⟶
∀ x1 .
x1
∈
SNoR
x0
⟶
∀ x2 : ο .
(
SNo
x1
⟶
SNoLev
x1
∈
SNoLev
x0
⟶
SNoLt
x0
x1
⟶
x2
)
⟶
x2
Known
SNoCutP_SNoCut_R
SNoCutP_SNoCut_R
:
∀ x0 x1 .
SNoCutP
x0
x1
⟶
∀ x2 .
x2
∈
x1
⟶
SNoLt
(
SNoCut
x0
x1
)
x2
Known
SNoCutP_SNo_SNoCut
SNoCutP_SNo_SNoCut
:
∀ x0 x1 .
SNoCutP
x0
x1
⟶
SNo
(
SNoCut
x0
x1
)
Known
and3I
and3I
:
∀ x0 x1 x2 : ο .
x0
⟶
x1
⟶
x2
⟶
and
(
and
x0
x1
)
x2
Known
SNoL_SNoS
SNoL_SNoS
:
∀ x0 .
SNo
x0
⟶
∀ x1 .
x1
∈
SNoL
x0
⟶
x1
∈
SNoS_
(
SNoLev
x0
)
Known
SNoR_SNoS
SNoR_SNoS
:
∀ x0 .
SNo
x0
⟶
∀ x1 .
x1
∈
SNoR
x0
⟶
x1
∈
SNoS_
(
SNoLev
x0
)
Definition
Subq
Subq
:=
λ x0 x1 .
∀ x2 .
x2
∈
x0
⟶
x2
∈
x1
Definition
TransSet
TransSet
:=
λ x0 .
∀ x1 .
x1
∈
x0
⟶
x1
⊆
x0
Known
ordinal_TransSet
ordinal_TransSet
:
∀ x0 .
ordinal
x0
⟶
TransSet
x0
Known
SNoLev_ordinal
SNoLev_ordinal
:
∀ x0 .
SNo
x0
⟶
ordinal
(
SNoLev
x0
)
Known
SNoS_I2
SNoS_I2
:
∀ x0 x1 .
SNo
x0
⟶
SNo
x1
⟶
SNoLev
x0
∈
SNoLev
x1
⟶
x0
∈
SNoS_
(
SNoLev
x1
)
Param
SNo_
SNo_
:
ι
→
ι
→
ο
Known
SNoS_E2
SNoS_E2
:
∀ x0 .
ordinal
x0
⟶
∀ x1 .
x1
∈
SNoS_
x0
⟶
∀ x2 : ο .
(
SNoLev
x1
∈
x0
⟶
ordinal
(
SNoLev
x1
)
⟶
SNo
x1
⟶
SNo_
(
SNoLev
x1
)
x1
⟶
x2
)
⟶
x2
Theorem
mul_SNo_prop_1
mul_SNo_prop_1
:
∀ x0 .
SNo
x0
⟶
∀ x1 .
SNo
x1
⟶
∀ x2 : ο .
(
SNo
(
mul_SNo
x0
x1
)
⟶
(
∀ x3 .
x3
∈
SNoL
x0
⟶
∀ x4 .
x4
∈
SNoL
x1
⟶
SNoLt
(
add_SNo
(
mul_SNo
x3
x1
)
(
mul_SNo
x0
x4
)
)
(
add_SNo
(
mul_SNo
x0
x1
)
(
mul_SNo
x3
x4
)
)
)
⟶
(
∀ x3 .
x3
∈
SNoR
x0
⟶
∀ x4 .
x4
∈
SNoR
x1
⟶
SNoLt
(
add_SNo
(
mul_SNo
x3
x1
)
(
mul_SNo
x0
x4
)
)
(
add_SNo
(
mul_SNo
x0
x1
)
(
mul_SNo
x3
x4
)
)
)
⟶
(
∀ x3 .
x3
∈
SNoL
x0
⟶
∀ x4 .
x4
∈
SNoR
x1
⟶
SNoLt
(
add_SNo
(
mul_SNo
x0
x1
)
(
mul_SNo
x3
x4
)
)
(
add_SNo
(
mul_SNo
x3
x1
)
(
mul_SNo
x0
x4
)
)
)
⟶
(
∀ x3 .
x3
∈
SNoR
x0
⟶
∀ x4 .
x4
∈
SNoL
x1
⟶
SNoLt
(
add_SNo
(
mul_SNo
x0
x1
)
(
mul_SNo
x3
x4
)
)
(
add_SNo
(
mul_SNo
x3
x1
)
(
mul_SNo
x0
x4
)
)
)
⟶
x2
)
⟶
x2
(proof)