Search for blocks/addresses/...
Proofgold Signed Transaction
vin
PrJAV..
/
c9982..
PUUC2..
/
c1bae..
vout
PrJAV..
/
9dd73..
6.57 bars
TMTfc..
/
fe1fb..
ownership of
5fae0..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TML94..
/
cae10..
ownership of
1458e..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMEgx..
/
fbb8d..
ownership of
234a4..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMTdP..
/
5cf4f..
ownership of
1fa99..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMYDg..
/
0d985..
ownership of
f66b9..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMZQj..
/
38e08..
ownership of
a4ea4..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMGiJ..
/
958ff..
ownership of
57702..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMWSE..
/
7f41b..
ownership of
2a2c2..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMTjJ..
/
75a79..
ownership of
6f716..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMcAc..
/
21fa3..
ownership of
334f5..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMXQj..
/
df5b2..
ownership of
d965e..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMSgp..
/
4d14a..
ownership of
7cc26..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMQby..
/
8b8e9..
ownership of
1f9d7..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMU5X..
/
7c83d..
ownership of
e907b..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMdn8..
/
f532d..
ownership of
22633..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMaev..
/
fff4e..
ownership of
8b6d3..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMQKb..
/
2f662..
ownership of
5e3cb..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMR45..
/
072ad..
ownership of
5c347..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMYRi..
/
2bbf5..
ownership of
7bad4..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMbWA..
/
4ade1..
ownership of
a5d9e..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMX7Y..
/
433d5..
ownership of
32548..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMHmD..
/
0e435..
ownership of
d4aff..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMG4a..
/
29a87..
ownership of
90c50..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMSVK..
/
abec2..
ownership of
9626c..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMdJC..
/
4fb7e..
ownership of
32022..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMQY2..
/
6382b..
ownership of
c82a7..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMU8Z..
/
41126..
ownership of
97b6d..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMQo8..
/
335cd..
ownership of
ffa8c..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMJpk..
/
cd310..
ownership of
d876a..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMQsG..
/
4e1e2..
ownership of
74a47..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMZud..
/
e8049..
ownership of
c65ee..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMaeW..
/
0a9ce..
ownership of
3f602..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMbVd..
/
bd6fb..
ownership of
8b265..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMbgK..
/
33f62..
ownership of
afd68..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMQ6J..
/
4e39c..
ownership of
53185..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMSQq..
/
fb395..
ownership of
74933..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMMXK..
/
9cb31..
ownership of
58c3b..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMdpG..
/
1fe00..
ownership of
5cb9d..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMR9f..
/
b622e..
ownership of
77393..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMF2R..
/
91f0e..
ownership of
cf993..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMTDN..
/
c116b..
ownership of
f689a..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMWwk..
/
51c98..
ownership of
c486a..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMZAc..
/
e5760..
ownership of
80491..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMSCg..
/
963e2..
ownership of
49ff5..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMFvq..
/
b1356..
ownership of
74e00..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMVus..
/
99462..
ownership of
4f3eb..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMPyg..
/
9707f..
ownership of
a90d3..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMSny..
/
70e16..
ownership of
6e2e0..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMVWd..
/
dbaf1..
ownership of
455a4..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMP3E..
/
e8998..
ownership of
7bd32..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMRkB..
/
66fe8..
ownership of
a74bc..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
TMa6k..
/
75e7d..
ownership of
63d72..
as prop with payaddr
Pr6Pc..
rights free controlledby
Pr6Pc..
upto 0
PUgbQ..
/
2f68a..
doc published by
Pr6Pc..
Definition
Subq
Subq
:=
λ x0 x1 .
∀ x2 .
x2
∈
x0
⟶
x2
∈
x1
Param
lam
Sigma
:
ι
→
(
ι
→
ι
) →
ι
Definition
setprod
setprod
:=
λ x0 x1 .
lam
x0
(
λ x2 .
x1
)
Known
Sigma_mon
Sigma_mon
:
∀ x0 x1 .
x0
⊆
x1
⟶
∀ x2 x3 :
ι → ι
.
(
∀ x4 .
x4
∈
x0
⟶
x2
x4
⊆
x3
x4
)
⟶
lam
x0
x2
⊆
lam
x1
x3
Theorem
setprod_mon
setprod_mon
:
∀ x0 x1 .
x0
⊆
x1
⟶
∀ x2 x3 .
x2
⊆
x3
⟶
setprod
x0
x2
⊆
setprod
x1
x3
(proof)
Known
Sigma_mon0
Sigma_mon0
:
∀ x0 x1 .
x0
⊆
x1
⟶
∀ x2 :
ι → ι
.
lam
x0
x2
⊆
lam
x1
x2
Theorem
setprod_mon0
setprod_mon0
:
∀ x0 x1 .
x0
⊆
x1
⟶
∀ x2 .
setprod
x0
x2
⊆
setprod
x1
x2
(proof)
Known
Subq_ref
Subq_ref
:
∀ x0 .
x0
⊆
x0
Theorem
setprod_mon1
setprod_mon1
:
∀ x0 x1 x2 .
x1
⊆
x2
⟶
setprod
x0
x1
⊆
setprod
x0
x2
(proof)
Param
setsum
setsum
:
ι
→
ι
→
ι
Param
ap
ap
:
ι
→
ι
→
ι
Param
ordsucc
ordsucc
:
ι
→
ι
Param
proj0
proj0
:
ι
→
ι
Known
proj0_ap_0
proj0_ap_0
:
∀ x0 .
proj0
x0
=
ap
x0
0
Param
proj1
proj1
:
ι
→
ι
Known
proj1_ap_1
proj1_ap_1
:
∀ x0 .
proj1
x0
=
ap
x0
1
Known
pair_eta_Subq_proj
pair_eta_Subq_proj
:
∀ x0 .
setsum
(
proj0
x0
)
(
proj1
x0
)
⊆
x0
Theorem
pair_eta_Subq
pair_eta_Subq
:
∀ x0 .
setsum
(
ap
x0
0
)
(
ap
x0
1
)
⊆
x0
(proof)
Known
proj_Sigma_eta
proj_Sigma_eta
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
lam
x0
x1
⟶
setsum
(
proj0
x2
)
(
proj1
x2
)
=
x2
Theorem
Sigma_eta
Sigma_eta
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
lam
x0
x1
⟶
setsum
(
ap
x2
0
)
(
ap
x2
1
)
=
x2
(proof)
Known
ReplEq_ext
ReplEq_ext
:
∀ x0 .
∀ x1 x2 :
ι → ι
.
(
∀ x3 .
x3
∈
x0
⟶
x1
x3
=
x2
x3
)
⟶
prim5
x0
x1
=
prim5
x0
x2
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
)
Theorem
ReplEq_setprod_ext
ReplEq_setprod_ext
:
∀ x0 x1 .
∀ x2 x3 :
ι →
ι → ι
.
(
∀ x4 .
x4
∈
x0
⟶
∀ x5 .
x5
∈
x1
⟶
x2
x4
x5
=
x3
x4
x5
)
⟶
{
x2
(
ap
x5
0
)
(
ap
x5
1
)
|x5 ∈
setprod
x0
x1
}
=
{
x3
(
ap
x5
0
)
(
ap
x5
1
)
|x5 ∈
setprod
x0
x1
}
(proof)
Definition
and
and
:=
λ x0 x1 : ο .
∀ x2 : ο .
(
x0
⟶
x1
⟶
x2
)
⟶
x2
Definition
tuple_p
tuple_p
:=
λ x0 x1 .
∀ x2 .
x2
∈
x1
⟶
∀ x3 : ο .
(
∀ x4 .
and
(
x4
∈
x0
)
(
∀ x5 : ο .
(
∀ x6 .
x2
=
setsum
x4
x6
⟶
x5
)
⟶
x5
)
⟶
x3
)
⟶
x3
Param
If_i
If_i
:
ο
→
ι
→
ι
→
ι
Known
exandE_i
exandE_i
:
∀ x0 x1 :
ι → ο
.
(
∀ x2 : ο .
(
∀ x3 .
and
(
x0
x3
)
(
x1
x3
)
⟶
x2
)
⟶
x2
)
⟶
∀ x2 : ο .
(
∀ x3 .
x0
x3
⟶
x1
x3
⟶
x2
)
⟶
x2
Known
andI
andI
:
∀ x0 x1 : ο .
x0
⟶
x1
⟶
and
x0
x1
Known
lamE
lamE
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
lam
x0
x1
⟶
∀ x3 : ο .
(
∀ x4 .
and
(
x4
∈
x0
)
(
∀ x5 : ο .
(
∀ x6 .
and
(
x6
∈
x1
x4
)
(
x2
=
setsum
x4
x6
)
⟶
x5
)
⟶
x5
)
⟶
x3
)
⟶
x3
Theorem
tuple_p_3_tuple
tuple_p_3_tuple
:
∀ x0 x1 x2 .
tuple_p
3
(
lam
3
(
λ x3 .
If_i
(
x3
=
0
)
x0
(
If_i
(
x3
=
1
)
x1
x2
)
)
)
(proof)
Theorem
tuple_p_4_tuple
tuple_p_4_tuple
:
∀ x0 x1 x2 x3 .
tuple_p
4
(
lam
4
(
λ x4 .
If_i
(
x4
=
0
)
x0
(
If_i
(
x4
=
1
)
x1
(
If_i
(
x4
=
2
)
x2
x3
)
)
)
)
(proof)
Param
Pi
Pi
:
ι
→
(
ι
→
ι
) →
ι
Known
PowerI
PowerI
:
∀ x0 x1 .
x1
⊆
x0
⟶
x1
∈
prim4
x0
Known
In_0_1
In_0_1
:
0
∈
1
Definition
False
False
:=
∀ x0 : ο .
x0
Definition
not
not
:=
λ x0 : ο .
x0
⟶
False
Definition
nIn
nIn
:=
λ x0 x1 .
not
(
x0
∈
x1
)
Known
Empty_eq
Empty_eq
:
∀ x0 .
(
∀ x1 .
nIn
x1
x0
)
⟶
x0
=
0
Definition
pair_p
pair_p
:=
λ x0 .
setsum
(
ap
x0
0
)
(
ap
x0
1
)
=
x0
Known
PiE
PiE
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
Pi
x0
x1
⟶
and
(
∀ x3 .
x3
∈
x2
⟶
and
(
pair_p
x3
)
(
ap
x3
0
∈
x0
)
)
(
∀ x3 .
x3
∈
x0
⟶
ap
x2
x3
∈
x1
x3
)
Param
Sing
Sing
:
ι
→
ι
Known
EmptyE
EmptyE
:
∀ x0 .
nIn
x0
0
Known
apI
apI
:
∀ x0 x1 x2 .
setsum
x1
x2
∈
x0
⟶
x2
∈
ap
x0
x1
Known
SingE
SingE
:
∀ x0 x1 .
x1
∈
Sing
x0
⟶
x1
=
x0
Known
Subq_1_Sing0
Subq_1_Sing0
:
1
⊆
Sing
0
Known
PowerE
PowerE
:
∀ x0 x1 .
x1
∈
prim4
x0
⟶
x1
⊆
x0
Theorem
Pi_Power_1
Pi_Power_1
:
∀ x0 .
∀ x1 :
ι → ι
.
(
∀ x2 .
x2
∈
x0
⟶
x1
x2
∈
prim4
1
)
⟶
Pi
x0
x1
∈
prim4
1
(proof)
Known
PiI
PiI
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
(
∀ x3 .
x3
∈
x2
⟶
and
(
pair_p
x3
)
(
ap
x3
0
∈
x0
)
)
⟶
(
∀ x3 .
x3
∈
x0
⟶
ap
x2
x3
∈
x1
x3
)
⟶
x2
∈
Pi
x0
x1
Definition
or
or
:=
λ x0 x1 : ο .
∀ x2 : ο .
(
x0
⟶
x2
)
⟶
(
x1
⟶
x2
)
⟶
x2
Known
xm
xm
:
∀ x0 : ο .
or
x0
(
not
x0
)
Known
Pi_eta
Pi_eta
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
Pi
x0
x1
⟶
lam
x0
(
ap
x2
)
=
x2
Known
beta0
beta0
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
nIn
x2
x0
⟶
ap
(
lam
x0
x1
)
x2
=
0
Theorem
Pi_0_dom_mon
Pi_0_dom_mon
:
∀ x0 x1 .
∀ x2 :
ι → ι
.
x0
⊆
x1
⟶
(
∀ x3 .
x3
∈
x1
⟶
nIn
x3
x0
⟶
0
∈
x2
x3
)
⟶
Pi
x0
x2
⊆
Pi
x1
x2
(proof)
Theorem
Pi_cod_mon
Pi_cod_mon
:
∀ x0 .
∀ x1 x2 :
ι → ι
.
(
∀ x3 .
x3
∈
x0
⟶
x1
x3
⊆
x2
x3
)
⟶
Pi
x0
x1
⊆
Pi
x0
x2
(proof)
Known
Subq_tra
Subq_tra
:
∀ x0 x1 x2 .
x0
⊆
x1
⟶
x1
⊆
x2
⟶
x0
⊆
x2
Theorem
Pi_0_mon
Pi_0_mon
:
∀ x0 x1 .
∀ x2 x3 :
ι → ι
.
(
∀ x4 .
x4
∈
x0
⟶
x2
x4
⊆
x3
x4
)
⟶
x0
⊆
x1
⟶
(
∀ x4 .
x4
∈
x1
⟶
nIn
x4
x0
⟶
0
∈
x3
x4
)
⟶
Pi
x0
x2
⊆
Pi
x1
x3
(proof)
Definition
setexp
setexp
:=
λ x0 x1 .
Pi
x1
(
λ x2 .
x0
)
Known
set_ext
set_ext
:
∀ x0 x1 .
x0
⊆
x1
⟶
x1
⊆
x0
⟶
x0
=
x1
Known
and3E
and3E
:
∀ x0 x1 x2 : ο .
and
(
and
x0
x1
)
x2
⟶
∀ x3 : ο .
(
x0
⟶
x1
⟶
x2
⟶
x3
)
⟶
x3
Known
Sigma_eta_proj0_proj1
Sigma_eta_proj0_proj1
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
lam
x0
x1
⟶
and
(
and
(
setsum
(
proj0
x2
)
(
proj1
x2
)
=
x2
)
(
proj0
x2
∈
x0
)
)
(
proj1
x2
∈
x1
(
proj0
x2
)
)
Known
tuple_pair
tuple_pair
:
∀ x0 x1 .
setsum
x0
x1
=
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
Known
lam_Pi
lam_Pi
:
∀ x0 .
∀ x1 x2 :
ι → ι
.
(
∀ x3 .
x3
∈
x0
⟶
x2
x3
∈
x1
x3
)
⟶
lam
x0
x2
∈
Pi
x0
x1
Known
If_i_or
If_i_or
:
∀ x0 : ο .
∀ x1 x2 .
or
(
If_i
x0
x1
x2
=
x1
)
(
If_i
x0
x1
x2
=
x2
)
Known
lamI
lamI
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
x0
⟶
∀ x3 .
x3
∈
x1
x2
⟶
setsum
x2
x3
∈
lam
x0
x1
Known
In_0_2
In_0_2
:
0
∈
2
Known
In_1_2
In_1_2
:
1
∈
2
Known
pair_p_I2
pair_p_I2
:
∀ x0 .
(
∀ x1 .
x1
∈
x0
⟶
and
(
pair_p
x1
)
(
ap
x1
0
∈
2
)
)
⟶
pair_p
x0
Theorem
setexp_2_eq
setexp_2_eq
:
∀ x0 .
setprod
x0
x0
=
setexp
x0
2
(proof)
Theorem
setexp_0_dom_mon
setexp_0_dom_mon
:
∀ x0 .
0
∈
x0
⟶
∀ x1 x2 .
x1
⊆
x2
⟶
setexp
x0
x1
⊆
setexp
x0
x2
(proof)
Theorem
setexp_0_mon
setexp_0_mon
:
∀ x0 x1 x2 x3 .
0
∈
x3
⟶
x2
⊆
x3
⟶
x0
⊆
x1
⟶
setexp
x2
x0
⊆
setexp
x3
x1
(proof)
Param
nat_p
nat_p
:
ι
→
ο
Known
nat_trans
nat_trans
:
∀ x0 .
nat_p
x0
⟶
∀ x1 .
x1
∈
x0
⟶
x1
⊆
x0
Theorem
nat_in_setexp_mon
nat_in_setexp_mon
:
∀ x0 .
0
∈
x0
⟶
∀ x1 .
nat_p
x1
⟶
∀ x2 .
x2
∈
x1
⟶
setexp
x0
x2
⊆
setexp
x0
x1
(proof)
Known
pair_tuple_fun
pair_tuple_fun
:
setsum
=
λ x1 x2 .
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x1
x2
)
Known
pairI0
pairI0
:
∀ x0 x1 x2 .
x2
∈
x0
⟶
setsum
0
x2
∈
setsum
x0
x1
Theorem
tupleI0
tupleI0
:
∀ x0 x1 x2 .
x2
∈
x0
⟶
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
0
x2
)
∈
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
(proof)
Known
pairI1
pairI1
:
∀ x0 x1 x2 .
x2
∈
x1
⟶
setsum
1
x2
∈
setsum
x0
x1
Theorem
tupleI1
tupleI1
:
∀ x0 x1 x2 .
x2
∈
x1
⟶
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
1
x2
)
∈
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
(proof)
Known
pairE
pairE
:
∀ x0 x1 x2 .
x2
∈
setsum
x0
x1
⟶
or
(
∀ x3 : ο .
(
∀ x4 .
and
(
x4
∈
x0
)
(
x2
=
setsum
0
x4
)
⟶
x3
)
⟶
x3
)
(
∀ x3 : ο .
(
∀ x4 .
and
(
x4
∈
x1
)
(
x2
=
setsum
1
x4
)
⟶
x3
)
⟶
x3
)
Theorem
tupleE
tupleE
:
∀ x0 x1 x2 .
x2
∈
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
⟶
or
(
∀ x3 : ο .
(
∀ x4 .
and
(
x4
∈
x0
)
(
x2
=
lam
2
(
λ x6 .
If_i
(
x6
=
0
)
0
x4
)
)
⟶
x3
)
⟶
x3
)
(
∀ x3 : ο .
(
∀ x4 .
and
(
x4
∈
x1
)
(
x2
=
lam
2
(
λ x6 .
If_i
(
x6
=
0
)
1
x4
)
)
⟶
x3
)
⟶
x3
)
(proof)
Known
tuple_2_Sigma
tuple_2_Sigma
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
x0
⟶
∀ x3 .
x3
∈
x1
x2
⟶
lam
2
(
λ x4 .
If_i
(
x4
=
0
)
x2
x3
)
∈
lam
x0
x1
Theorem
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
(proof)
Theorem
tuple_Sigma_eta
tuple_Sigma_eta
:
∀ x0 .
∀ x1 :
ι → ι
.
∀ x2 .
x2
∈
lam
x0
x1
⟶
lam
2
(
λ x4 .
If_i
(
x4
=
0
)
(
ap
x2
0
)
(
ap
x2
1
)
)
=
x2
(proof)
Theorem
apI2
apI2
:
∀ x0 x1 x2 .
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x1
x2
)
∈
x0
⟶
x2
∈
ap
x0
x1
(proof)
Known
apE
apE
:
∀ x0 x1 x2 .
x2
∈
ap
x0
x1
⟶
setsum
x1
x2
∈
x0
Theorem
apE2
apE2
:
∀ x0 x1 x2 .
x2
∈
ap
x0
x1
⟶
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x1
x2
)
∈
x0
(proof)
Known
Empty_Subq_eq
Empty_Subq_eq
:
∀ x0 .
x0
⊆
0
⟶
x0
=
0
Theorem
ap_const_0
ap_const_0
:
∀ x0 .
ap
0
x0
=
0
(proof)
Known
tuple_2_eta
tuple_2_eta
:
∀ x0 x1 .
lam
2
(
ap
(
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
)
)
=
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
Known
cases_2
cases_2
:
∀ x0 .
x0
∈
2
⟶
∀ x1 :
ι → ο
.
x1
0
⟶
x1
1
⟶
x1
x0
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
Theorem
tuple_2_in_A_2
tuple_2_in_A_2
:
∀ x0 x1 x2 .
x0
∈
x2
⟶
x1
∈
x2
⟶
lam
2
(
λ x3 .
If_i
(
x3
=
0
)
x0
x1
)
∈
setexp
x2
2
(proof)
Param
bij
bij
:
ι
→
ι
→
(
ι
→
ι
) →
ο
Known
PigeonHole_nat_bij
PigeonHole_nat_bij
:
∀ x0 .
nat_p
x0
⟶
∀ x1 :
ι → ι
.
(
∀ x2 .
x2
∈
x0
⟶
x1
x2
∈
x0
)
⟶
(
∀ x2 .
x2
∈
x0
⟶
∀ x3 .
x3
∈
x0
⟶
x1
x2
=
x1
x3
⟶
x2
=
x3
)
⟶
bij
x0
x0
x1
Known
nat_2
nat_2
:
nat_p
2
Theorem
tuple_2_bij_2
tuple_2_bij_2
:
∀ x0 x1 .
x0
∈
2
⟶
x1
∈
2
⟶
(
x0
=
x1
⟶
∀ x2 : ο .
x2
)
⟶
bij
2
2
(
ap
(
lam
2
(
λ x2 .
If_i
(
x2
=
0
)
x0
x1
)
)
)
(proof)