I just review the computing theorem. And i met a question as follow.
Consider a deterministic ktape
Turing machine with q
states
and σ
alphabetic symbols. Suppose this Turing machine halts after using a
maximum of h
cells on each of the tapes. What is the maximum running time?
why the answer is q X(σ^hk)X(h^k)
?
And what is σ^hk
and h^k
means? thanks!


The key insight is that in order for a Turing machine to halt, it cannot enter a loop. Since a Turing machine will always follow the same sequence after being a specific state, if it ever becomes that same state twice, we know the machine is caught in an infinite loop and will never finish. Therefore, the theoretical maximum number of steps it can run is the maximum number of possible different states for the machine without being the same exact state twice. In this example, a unique state is made of:
Since there are For (2), there is an additional For (3), each of the machine heads can also independently be in one of the So the total number of possible states is the product of 


Think of your Turing machine as a Linear Bounded Automaton (LBA), that works within the bound of h*k. Let's first consider single tape machine. For a single tape LBA, if a LBA has: 1) then the number of its possible configurations is Put it simple, that for a single tape LBA, we have To generalize it for a ktape machine, there are Change 


^
here probably represents "to the power of", soσ^hk
is "σ to the power of (h multiplied by k)"  that is "number of alphabetic symbols multiplied by itself the same number of times as there are total cells (cells per tape multiplied by number of tapes). – IMSoP Nov 4 '13 at 4:23