We will show that
B
n
(
m
)
{\displaystyle B_{n}(m)}
3
↑
n
/
2
m
{\displaystyle 3\uparrow ^{n/2}m}
B
B
n
{\displaystyle BB_{n}}
3
↑
n
/
2
3
{\displaystyle 3\uparrow ^{n/2}3}
Knuth's up-arrow notation and User:sligocki/up-arrow properties ).
Claim.
B
2
k
+
3
(
m
)
≥
3
↑
k
m
{\displaystyle B_{2k+3}(m)\geq 3\uparrow ^{k}m}
k
≥
−
2
{\displaystyle k\geq -2}
m
≥
0
{\displaystyle m\geq 0}
Proof by induction. Base Case
B
2
k
+
3
(
0
)
=
1
≥
1
=
3
↑
k
0
{\displaystyle B_{2k+3}(0)=1\geq 1=3\uparrow ^{k}0}
B
1
(
m
)
=
m
+
1
≥
m
+
1
=
3
↑
−
2
m
{\displaystyle B_{1}(m)=m+1\geq m+1=3\uparrow ^{-2}m}
Inductive Step
Assume that
B
2
k
′
+
3
(
m
′
)
≥
3
↑
k
′
m
′
{\displaystyle B_{2k^{\prime }+3}(m^{\prime })\geq 3\uparrow ^{k^{\prime }}m^{\prime }}
k
′
=
k
,
m
′
<
m
{\displaystyle k^{\prime }=k,m^{\prime }<m}
k
′
<
k
,
m
′
<
3
↑
k
(
m
−
1
)
{\displaystyle k^{\prime }<k,m^{\prime }<3\uparrow ^{k}(m-1)}
B
2
k
+
3
(
m
)
=
B
2
k
+
1
[
B
2
k
+
3
(
m
−
1
)
+
1
]
+
1
>
B
2
k
+
1
[
3
↑
k
(
m
−
1
)
]
>
3
↑
k
−
1
[
3
↑
k
(
m
−
1
)
]
=
3
↑
k
m
{\displaystyle B_{2k+3}(m)=B_{2k+1}[B_{2k+3}(m-1)+1]+1>B_{2k+1}[3\uparrow ^{k}(m-1)]>3\uparrow ^{k-1}[3\uparrow ^{k}(m-1)]=3\uparrow ^{k}m\,}
QED
Claim.
B
2
k
+
3
(
m
)
<
1
2
(
3
↑
k
(
m
+
2
)
)
<
(
3
↑
k
(
m
+
2
)
)
{\displaystyle B_{2k+3}(m)<{\frac {1}{2}}(3\uparrow ^{k}(m+2))<(3\uparrow ^{k}(m+2))}
k
≥
1
{\displaystyle k\geq 1}
m
≥
0
{\displaystyle m\geq 0}
m +1 for k ≥ 2)Proof by induction. Base Case
B
2
k
+
3
(
0
)
=
1
<
1
2
(
3
↑
k
2
)
{\displaystyle B_{2k+3}(0)=1<{\frac {1}{2}}(3\uparrow ^{k}2)}
B
5
(
m
)
=
9
2
3
m
<
1
2
(
3
↑
(
m
+
2
)
)
{\displaystyle B_{5}(m)={\frac {9}{2}}3^{m}<{\frac {1}{2}}(3\uparrow (m+2))}
B
7
(
m
)
<
1
2
(
3
↑
2
(
m
+
1
)
)
{\displaystyle B_{7}(m)<{\frac {1}{2}}(3\uparrow ^{2}(m+1))}
Inductive Step
Assume that
B
2
k
′
+
3
(
m
′
)
<
1
2
(
3
↑
k
′
(
m
′
+
2
)
)
{\displaystyle B_{2k^{\prime }+3}(m^{\prime })<{\frac {1}{2}}(3\uparrow ^{k^{\prime }}(m^{\prime }+2))}
k
′
=
k
,
m
′
<
m
{\displaystyle k^{\prime }=k,m^{\prime }<m}
k
′
<
k
,
m
′
<
3
↑
k
m
+
1
{\displaystyle k^{\prime }<k,m^{\prime }<3\uparrow ^{k}m+1}
B
2
k
+
3
(
m
)
=
B
2
k
+
1
[
B
2
k
+
3
(
m
−
1
)
+
1
]
+
1
<
B
2
k
+
1
[
1
2
(
3
↑
k
(
m
+
1
)
)
+
1
]
+
1
<
1
2
(
3
↑
k
−
1
[
1
2
(
3
↑
k
(
m
+
1
)
)
+
3
]
)
+
1
≤
?
1
2
(
3
↑
k
−
1
[
1
2
(
3
↑
k
(
m
+
1
)
)
+
4
]
)
≤
?
1
2
(
3
↑
k
−
1
(
3
↑
k
(
m
+
1
)
)
)
=
1
2
(
3
↑
k
(
m
+
2
)
)
{\displaystyle {\begin{array}{rll}B_{2k+3}(m)=B_{2k+1}[B_{2k+3}(m-1)+1]+1&<&B_{2k+1}[{\frac {1}{2}}(3\uparrow ^{k}(m+1))+1]+1\\&<&{\frac {1}{2}}(3\uparrow ^{k-1}[{\frac {1}{2}}(3\uparrow ^{k}(m+1))+3])+1\\&\leq ?&{\frac {1}{2}}(3\uparrow ^{k-1}[{\frac {1}{2}}(3\uparrow ^{k}(m+1))+4])\\&\leq ?&{\frac {1}{2}}(3\uparrow ^{k-1}(3\uparrow ^{k}(m+1)))\\&=&{\frac {1}{2}}(3\uparrow ^{k}(m+2))\end{array}}}
≤? statements seem obvious, but grungy to prove (left as an exercise to the reader :)
Claim.
3
↑
k
3
<
B
B
2
k
+
4
,
B
B
2
k
+
5
<
3
↑
k
+
1
3
{\displaystyle 3\uparrow ^{k}3<BB_{2k+4},BB_{2k+5}<3\uparrow ^{k+1}3}
k
≥
1
{\displaystyle k\geq 1}
Proof.
B
B
2
k
+
5
=
B
2
k
+
3
(
B
2
k
+
3
(
1
)
)
>
3
↑
k
(
3
↑
k
1
)
=
3
↑
k
3
{\displaystyle BB_{2k+5}=B_{2k+3}(B_{2k+3}(1))>3\uparrow ^{k}(3\uparrow ^{k}1)=3\uparrow ^{k}3}
B
B
2
k
+
4
>
B
2
k
+
1
(
B
2
k
+
1
(
3
)
)
>
3
↑
k
−
1
(
3
↑
k
−
1
3
)
=
3
↑
k
3
{\displaystyle BB_{2k+4}>B_{2k+1}(B_{2k+1}(3))>3\uparrow ^{k-1}(3\uparrow ^{k-1}3)=3\uparrow ^{k}3}
B
B
2
k
+
5
=
B
2
k
+
3
(
B
2
k
+
3
(
1
)
)
<
1
2
(
3
↑
k
(
1
2
(
3
↑
k
(
1
+
2
)
)
+
2
)
)
<
3
↑
k
(
3
↑
k
3
)
=
3
↑
k
+
1
3
{\displaystyle BB_{2k+5}=B_{2k+3}(B_{2k+3}(1))<{\frac {1}{2}}(3\uparrow ^{k}({\frac {1}{2}}(3\uparrow ^{k}(1+2))+2))<3\uparrow ^{k}(3\uparrow ^{k}3)=3\uparrow ^{k+1}3}
B
B
2
k
+
4
=
B
2
k
+
1
[
B
2
k
+
1
(
3
)
+
1
]
+
1
<
1
2
(
3
↑
k
−
1
(
1
2
(
3
↑
k
−
1
(
3
+
2
)
)
+
3
)
)
+
1
<
3
↑
k
−
1
(
3
↑
k
−
1
5
)
<
3
↑
k
4
<
3
↑
k
+
1
3
{\displaystyle BB_{2k+4}=B_{2k+1}[B_{2k+1}(3)+1]+1<{\frac {1}{2}}(3\uparrow ^{k-1}({\frac {1}{2}}(3\uparrow ^{k-1}(3+2))+3))+1<3\uparrow ^{k-1}(3\uparrow ^{k-1}5)<3\uparrow ^{k}4<3\uparrow ^{k+1}3}
QED
^ Milton W. Green. A Lower Bound on Rado's Sigma Function for Binary Turing Machines. In Preceedings of the IEEE Fifth Annual Symposium on Switching Circuits Theory and Logical Design , pages 91–94, 1964.
![{\displaystyle B_{n}(m)=B_{n-2}[B_{n}(m-1)+1]+1}](https://wikimedia.org/api/rest_v1/media/math/render/svg/ff1acf2d3af558008d8ba06b96344689ce9c7d2e)
![{\displaystyle BB_{n}=B_{n-2}[B_{n-2}(1)]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/9cb1b95b6af78cc6f159c32dd0d12f4ff40daac8)
![{\displaystyle BB_{n}=B_{n-3}[B_{n-3}(3)+1]+1}](https://wikimedia.org/api/rest_v1/media/math/render/svg/a2048aeaa34d989f4aaf518662253369d47d7b0f)
![{\displaystyle B_{2k+3}(m)=B_{2k+1}[B_{2k+3}(m-1)+1]+1>B_{2k+1}[3\uparrow ^{k}(m-1)]>3\uparrow ^{k-1}[3\uparrow ^{k}(m-1)]=3\uparrow ^{k}m\,}](https://wikimedia.org/api/rest_v1/media/math/render/svg/e63f185b90f04ff62212705ac870ee6d00ed9eff)
![{\displaystyle {\begin{array}{rll}B_{2k+3}(m)=B_{2k+1}[B_{2k+3}(m-1)+1]+1&<&B_{2k+1}[{\frac {1}{2}}(3\uparrow ^{k}(m+1))+1]+1\\&<&{\frac {1}{2}}(3\uparrow ^{k-1}[{\frac {1}{2}}(3\uparrow ^{k}(m+1))+3])+1\\&\leq ?&{\frac {1}{2}}(3\uparrow ^{k-1}[{\frac {1}{2}}(3\uparrow ^{k}(m+1))+4])\\&\leq ?&{\frac {1}{2}}(3\uparrow ^{k-1}(3\uparrow ^{k}(m+1)))\\&=&{\frac {1}{2}}(3\uparrow ^{k}(m+2))\end{array}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/28f8ac74e12fda64188f0537c6c0f2ab448b4a49)
![{\displaystyle BB_{2k+4}=B_{2k+1}[B_{2k+1}(3)+1]+1<{\frac {1}{2}}(3\uparrow ^{k-1}({\frac {1}{2}}(3\uparrow ^{k-1}(3+2))+3))+1<3\uparrow ^{k-1}(3\uparrow ^{k-1}5)<3\uparrow ^{k}4<3\uparrow ^{k+1}3}](https://wikimedia.org/api/rest_v1/media/math/render/svg/b7dcc1f25057f8f52fa3a55b4c16acdf3b56b254)