Perko pair knots
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We can also prove that two knots are the same by working with their projections. A '''projection''' of a knot is a flat representation of it, essentially a 2D drawing of the knot. There are many ways to use projections to show that certain knots are distinct from each other, but the main way of using projections to demonstrate that two knots are the same is to use the Reidemeister moves, which are described below. | We can also prove that two knots are the same by working with their projections. A '''projection''' of a knot is a flat representation of it, essentially a 2D drawing of the knot. There are many ways to use projections to show that certain knots are distinct from each other, but the main way of using projections to demonstrate that two knots are the same is to use the Reidemeister moves, which are described below. | ||
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+ | ==Reidemeister moves== | ||
- | As was stated above, knots are considered to be the same if one can be rearranged into the other without breaking the string or passing it through itself. This kind of transformation is called an '''ambient isotopy'''. | + | As was stated above, knots are considered to be the same if one can be rearranged into the other without breaking the string or passing it through itself. This kind of transformation is called an '''ambient isotopy'''. But when we're writing a written proof, we have to work with the knots projection, instead of the knot itself. What manipulations can we make on a knot’s projection that correspond to ambient isotopies in three dimensions? |
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- | ==Proving that the Perko | + | ==Proving that the Perko knots are equivalent== |
- | In his paper "On the Classification of Knots", Kenneth Perko provided an | + | In his paper "On the Classification of Knots", Kenneth Perko provided an abridged proof that the knots now known as the Perko pair are the same. This proof is shown below: |
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[[Image:Perko 42A.gif|160px]] | [[Image:Perko 42A.gif|160px]] | ||
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- | Perko's proof relies on the ability of the reader to manipulate the knots in their head and verify that each projection can be manipulated to look like the next. To create a full, rigorous proof, we need to use planar isotopies and the Reidmeister | + | Perko's proof relies on the ability of the reader to manipulate the knots in their head and verify that each projection can be manipulated to look like the next. To create a full, rigorous proof, we need to use planar isotopies and the Reidmeister moves, as described above. |
Below is a step-by-step Reidemeister moves proof that follows the outline of Perko's shorter proof. The arrows between each step are labeled to show how we get from one image to the other: "p.i." means we use a planar isotopy, "I" means we use the first Reidemeister move, "II" means we use the second move, and "III" means we use the third move. Mousing over a step will highlight the part of the knot that's about to move in pink, and display a dotted green line showing where it will move to. | Below is a step-by-step Reidemeister moves proof that follows the outline of Perko's shorter proof. The arrows between each step are labeled to show how we get from one image to the other: "p.i." means we use a planar isotopy, "I" means we use the first Reidemeister move, "II" means we use the second move, and "III" means we use the third move. Mousing over a step will highlight the part of the knot that's about to move in pink, and display a dotted green line showing where it will move to. |
Revision as of 16:21, 14 July 2011
- This is a picture of the Perko pair knots. They were first thought to be separate knots, but in 1974 it was proved that they were actually the same knot.
Perko pair knots |
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Contents |
Basic Description
In 1899, C. N. Little published a table of 43 nonalternating knots of 10 crossings that listed these two knots as being distinct. Seventy-five years later, Kenneth Perko, a lawyer and part-time mathematician, discovered that these were actually the same knot^{[1]}.To say that two knots are the same is to say that one can be deformed into the other without breaking the knot or passing it through itself. To prove that two knots are the same, we can create one of them out of actual rope, and tug at it and move it around until it looks like the other. As the story goes, that's how Perko figured out that these knots are the same - by working with rope on his floor.
We can also prove that two knots are the same by working with their projections. A projection of a knot is a flat representation of it, essentially a 2D drawing of the knot. There are many ways to use projections to show that certain knots are distinct from each other, but the main way of using projections to demonstrate that two knots are the same is to use the Reidemeister moves, which are described below.
A More Mathematical Explanation
Reidemeister moves
As was stated above, knots are considered to be the same if one can be rearra [...]Reidemeister moves
As was stated above, knots are considered to be the same if one can be rearranged into the other without breaking the string or passing it through itself. This kind of transformation is called an ambient isotopy. But when we're writing a written proof, we have to work with the knots projection, instead of the knot itself. What manipulations can we make on a knot’s projection that correspond to ambient isotopies in three dimensions?
The first answer is a planar isotopy. A planar isotopy is the sort of transformation you could make if the projection of a knot was printed on very stretchy rubber. The image can be stretched in all directions, but none of the crossings are affected:
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The original image. |
These are planar isotopies. |
This is not a planar isotopy. |
The second answer is the Reidemeister moves, a set of three changes you can make to a knot’s projection that do affect the knot’s crossings but are still ambient isotopies:
Proving that the Perko knots are equivalent
In his paper "On the Classification of Knots", Kenneth Perko provided an abridged proof that the knots now known as the Perko pair are the same. This proof is shown below:
Perko's proof relies on the ability of the reader to manipulate the knots in their head and verify that each projection can be manipulated to look like the next. To create a full, rigorous proof, we need to use planar isotopies and the Reidmeister moves, as described above.
Below is a step-by-step Reidemeister moves proof that follows the outline of Perko's shorter proof. The arrows between each step are labeled to show how we get from one image to the other: "p.i." means we use a planar isotopy, "I" means we use the first Reidemeister move, "II" means we use the second move, and "III" means we use the third move. Mousing over a step will highlight the part of the knot that's about to move in pink, and display a dotted green line showing where it will move to.
Why It's Interesting
Interest in comparing and tabulating knots actually grew out of a mistaken theory in chemistry. In the 1880s, chemists believed that space was filled with something called ether, and Lord Kelvin proposed that different atoms were different types of knots in the ether^{[1]}.Belief in ether soon faded, but interest in identifying and cataloging different types of knots stayed. In 1899, the Perko knots were published as distinct knots in C. N. Little's table of 43 nonalternating knots of 10 crossings^{[1]}. These knots were believed to be distinct until 1974, when Kenneth Perko published a paper titled "On the Classification of Knots" that demonstrated that they were in fact the same.
The Perko knots are sometimes used to illustrate the point that knot theory is still a relatively young mathematical field, and that it is accessible to non-mathematicians.
Teaching Materials
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References
- ↑ ^{1.0} ^{1.1} ^{1.2} Adams, C. (2004). The knot book: An elementary introduction to the mathematical theory of knots. Providence, RI: American Mathematical Society.
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