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rdfs:comment | - The tetratri is equal to {3,3,3,3} = 33 (3 powerexploded to 3) in BEAF. It can also be written 4 & 3, using the array of operator. The term was coined by Jonathan Bowers. It is larger than Graham's number and comparable to Sbiis Saibian's grinningolthra. Tetratri can be computed in 2-bracket operator notation using the following process:
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abstract | - The tetratri is equal to {3,3,3,3} = 33 (3 powerexploded to 3) in BEAF. It can also be written 4 & 3, using the array of operator. The term was coined by Jonathan Bowers. It is larger than Graham's number and comparable to Sbiis Saibian's grinningolthra. Tetratri can be computed in 2-bracket operator notation using the following process:
* \(t_1 = 3\)
* \(t_2 = 3 \{\{ 3 \{\{ 3 \}\} 3 \}\} 3\)
* \(t_3 = 3 \{\{ 3 \{\{ 3 \{\{ \cdots \{\{ 3 \}\} \cdots \}\} 3 \}\} 3 \}\} 3\) with \(t_2\) 3's from center out.
* \(t_4 = 3 \{\{ 3 \{\{ 3 \{\{ \cdots \{\{ 3 \}\} \cdots \}\} 3 \}\} 3 \}\} 3\) with \(t_3\) 3's from center out.
* etc.
* Tetratri is \(t_{t_{t_\cdots1}}\), where there are \(t_{t_{t_1}}\) t's.
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