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Indexed Cube Lovers Archive
Order of the Additive List
Submitted by cubex on Thu, 03/10/2005 - 02:39.
Conjecture:
The order of the additive list always evenly
divides the order of the generated group.
Time for some definitions.
First from the possible moves of the cube using Singmaster notation (U, D, F, B, L, R) pick any number of operators, this is the basis for the generated group.
The group generated by < U, F, D > is an example of the "generated group".
From these operators we can generate the "additive list" so the elements are
{ U, UF, UFD, UFDU, UFDUF, UFDUFD ... }
Now for some rules...
Pick only one of _each_ of the 6 operators UDFBLR. Any number of operators may be used from 1 to all 6. Using the inverse of an operator is allowed. For now we shall keep things in the quarter turn metric so there is no use of op^2 only op or -op.
Once we pick an op we don't use that op again until we repeat.
So in my example of < U, F, D > we can have { -U, -UF, -UFD, -UFD-U ... } but not { -U, -UF, -UFU ... } as this breaks the rule of only one use of a specific op before repeating begins.
The order of the additive list is the number of ops times the order N where N is { op1, op2, op3 ... }^N = I.
In my example using < U, F, D> the order of the additive list 3 * 90 = 270, since { U, F, D }^90 = I.
Sizeof(ufd) = 159993501696000.
Then the conjecture predicts these numbers divide evenly:
159993501696000 / 270 = 592568524800.
So let's try another additive list, this time we will pick -U instead of U.
Now we have {-U, F, D }^180 = I. Size of the additive list is 3 times 180 = 540.
Again the Sizeof(ufd) is 159993501696000. Then 159993501696000 divided by 540 is 296284262400.
There are a lot of additive lists but not a huge number so I think it is possible to try all examples. So far no one has found any counter-examples but we have not tried all the possible lists.
Time for some definitions.
First from the possible moves of the cube using Singmaster notation (U, D, F, B, L, R) pick any number of operators, this is the basis for the generated group.
The group generated by < U, F, D > is an example of the "generated group".
From these operators we can generate the "additive list" so the elements are
{ U, UF, UFD, UFDU, UFDUF, UFDUFD ... }
Now for some rules...
Pick only one of _each_ of the 6 operators UDFBLR. Any number of operators may be used from 1 to all 6. Using the inverse of an operator is allowed. For now we shall keep things in the quarter turn metric so there is no use of op^2 only op or -op.
Once we pick an op we don't use that op again until we repeat.
So in my example of < U, F, D > we can have { -U, -UF, -UFD, -UFD-U ... } but not { -U, -UF, -UFU ... } as this breaks the rule of only one use of a specific op before repeating begins.
The order of the additive list is the number of ops times the order N where N is { op1, op2, op3 ... }^N = I.
In my example using < U, F, D> the order of the additive list 3 * 90 = 270, since { U, F, D }^90 = I.
Sizeof(ufd) = 159993501696000.
Then the conjecture predicts these numbers divide evenly:
159993501696000 / 270 = 592568524800.
So let's try another additive list, this time we will pick -U instead of U.
Now we have {-U, F, D }^180 = I. Size of the additive list is 3 times 180 = 540.
Again the Sizeof(ufd) is 159993501696000. Then 159993501696000 divided by 540 is 296284262400.
There are a lot of additive lists but not a huge number so I think it is possible to try all examples. So far no one has found any counter-examples but we have not tried all the possible lists.
