Difference between revisions of "Equivalent patterns"

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We say that two hex [[pattern]]s (subsets of a board) are '''equivalent patterns''' if, when one of them occurs embedded in ''any'' hex board, it could be replaced by the other and the side who has winning strategy does not change.
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We say that two Hex [[pattern]]s (subsets of a board) are '''equivalent patterns''' if, when one of them occurs embedded in ''any'' Hex board, it could be replaced by the other and the side who has winning strategy does not change.
  
 
== Equivalence by capture ==
 
== Equivalence by capture ==
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The blue stone in the left pattern is [[captured cell|captured]] by Red. Therefore, the position is equivalent to one where this stone is actually red.
 
The blue stone in the left pattern is [[captured cell|captured]] by Red. Therefore, the position is equivalent to one where this stone is actually red.
  
The knowledge of equivalent patterns turns out to be very useful to play Hex, because it allows you to disregard some pieces in the board, or prune the analysis tree. In my opinion, some patterns lead to positions that are much more clear than other equivalent patterns. My intention here is to write always in second place such pattens, and the use that I make of equivalent patterns is that in my games, mentally I always replace the first patterns by the equivalent counterparts.
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The knowledge of equivalent patterns turns out to be very useful for playing Hex, because it allows the player to disregard some pieces in the board, or prune the analysis tree. Some positions are much clearer than other equivalent positions. In the examples below, the simpler pattern is usually written on the right. One can make use of these equivalent patterns by mentally always replacing the left pattern with the right one.
  
 
Here are several examples of pairs of equivalent positions, and a short explanation on the way to prove them so.
 
Here are several examples of pairs of equivalent positions, and a short explanation on the way to prove them so.
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The equivalence is obtained by applying two times the example 1.
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The equivalence is obtained by applying example 1 twice.
  
Both examples before are instances of the following rule to produce equivalence pairs. Given a [[chain]] G, let the '''neighborhood''' of G, neigh(G), be the set of cells next to one of those in G but not belonging to it. In a given pattern P<sub>1</sub>, suppose that G is a chain owned by the player A, and that C is a cell in neigh(G) such that any cell of A next to C belongs to G. Let P<sub>2</sub> be the pattern that results when A occupies C (removing an opponent stone, if necessary), therefore P<sub>2</sub> contains a chain G' containing G and C. If neigh(G')=neigh(G) then P<sub>1</sub> and P<sub>2</sub> are equivalent.
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Both above examples are instances of the following rule to produce equivalence pairs. Given a [[chain]] G, let the '''neighborhood''' of G, neigh(G), be the set of cells that are adjacent to G but do not belong to it. In a given pattern P<sub>1</sub>, suppose that G is a red chain, and that C is a cell in neigh(G), which may be empty or occupied by Blue. Let P<sub>2</sub> be the result of placing a red piece in C (removing a Blue stone, if necessary). Therefore P<sub>2</sub> contains a chain G' containing G and C. If neigh(G')=neigh(G) then P<sub>1</sub> and P<sub>2</sub> are equivalent. Of course the dual argument also holds for blue chains.
  
 
This rule justifies the following equivalent pairs:
 
This rule justifies the following equivalent pairs:
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Another rule producing equivalent patterns: If there are two empty cells C<sub>1</sub> and C<sub>2</sub> in a pattern, such that if the opponent of the player A occupies one of them, A can occupy the other capturing the latter, then an equivalent position is obtained if both C<sub>1</sub> and C<sub>2</sub> are occupied by A.
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Another rule producing equivalent patterns: If there are two empty cells C<sub>1</sub> and C<sub>2</sub> in a pattern, such that if Blue occupies one of them, Red can occupy the other capturing the former, then an equivalent position is obtained if both C<sub>1</sub> and C<sub>2</sub> are occupied by Red.
  
Equivalent pairs obtained with such rule:
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Equivalent pairs obtained with this rule:
  
 
=== Example 5 ===
 
=== Example 5 ===
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This is a very instructive pattern because it shows that playing 2 rows out from a [[friendly]] edge with 2 free cells on the first row below the play is equivalent to playing at all three cells simultaneously, and hence at least as good as playing at either cell on the first row.  So as a rule, never play on the first row in such a situation.  We can see this by viewing the 3 upper red stones as part of a friendly edge.
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This is a very instructive pattern because it shows that playing 2 rows out from a [[friendly]] edge with 2 free cells on the first row below the play is equivalent to playing at all three cells simultaneously, and hence at least as good as playing at either cell on the first row.  So as a rule, one should never play on the first row in such a situation.  We can see this by viewing the 3 upper red stones as part of a friendly edge.
  
This pattern, along with Example 4 can be used to show that the two move start A1 + B1 (or either single move) for Red loses on a board 3x3 or bigger:
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This pattern, along with Example 4, can be used to show that the 2-move opening a1 + b1 (or either single move) for Red loses on a board 3x3 or bigger:
  
 
=== Example 5b (Opening A1+B1 loses) ===
 
=== Example 5b (Opening A1+B1 loses) ===
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So, in response to a1+b1 by Red, Blue can play at b2. This captures a2 and a3 by Example 5, and then a1 and b1 by applying Example 1 twice. Thus, the left position is equivalent to the right one. This includes the cells a1 and a2, so the original position is losing for Red by a strategy stealing argument.
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In response to a1+b1 by Red, Blue can play at b2. This captures a2 and a3 by Example 5, and then a1 and b1 by applying Example 1 twice. Thus, the left position is equivalent to the right one. This includes the cells a1 and a2, so the original position is losing for Red by a strategy stealing argument.
  
 
In fact, making the opening play b2 is equivalent to playing 5 stones at a1, a2, b1, b1, and c1. However this is known to produce a losing position on boards of size 4, 7 & 8 (see [[small boards]]).
 
In fact, making the opening play b2 is equivalent to playing 5 stones at a1, a2, b1, b1, and c1. However this is known to produce a losing position on boards of size 4, 7 & 8 (see [[small boards]]).
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Third rule for equivalent patterns (rather obvious) rule: Any area surrounded by a single chain of each enemy may be randomly filled. This happens because the outcome of the game does not depend on it at all.
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Here is a third (rather obvious) rule for equivalent patterns: Any area surrounded by a single chain of the opponent may be randomly filled. This happens because the outcome of the game does not depend on it at all.
  
 
== Equivalence for reasons other than capture ==
 
== Equivalence for reasons other than capture ==

Revision as of 02:40, 8 December 2020

We say that two Hex patterns (subsets of a board) are equivalent patterns if, when one of them occurs embedded in any Hex board, it could be replaced by the other and the side who has winning strategy does not change.

Equivalence by capture

Cells that are captured by one player can be filled in with stones of that player's color.

Example 1

For example, the two patterns below are equivalent, and an example of what is known as the useless triangle.

and

The blue stone in the left pattern is captured by Red. Therefore, the position is equivalent to one where this stone is actually red.

The knowledge of equivalent patterns turns out to be very useful for playing Hex, because it allows the player to disregard some pieces in the board, or prune the analysis tree. Some positions are much clearer than other equivalent positions. In the examples below, the simpler pattern is usually written on the right. One can make use of these equivalent patterns by mentally always replacing the left pattern with the right one.

Here are several examples of pairs of equivalent positions, and a short explanation on the way to prove them so.

Example 2

and

The equivalence is obtained by applying example 1 twice.

Both above examples are instances of the following rule to produce equivalence pairs. Given a chain G, let the neighborhood of G, neigh(G), be the set of cells that are adjacent to G but do not belong to it. In a given pattern P1, suppose that G is a red chain, and that C is a cell in neigh(G), which may be empty or occupied by Blue. Let P2 be the result of placing a red piece in C (removing a Blue stone, if necessary). Therefore P2 contains a chain G' containing G and C. If neigh(G')=neigh(G) then P1 and P2 are equivalent. Of course the dual argument also holds for blue chains.

This rule justifies the following equivalent pairs:

Example 3

and

Example 4

and

Another rule producing equivalent patterns: If there are two empty cells C1 and C2 in a pattern, such that if Blue occupies one of them, Red can occupy the other capturing the former, then an equivalent position is obtained if both C1 and C2 are occupied by Red.

Equivalent pairs obtained with this rule:

Example 5

and

This is a very instructive pattern because it shows that playing 2 rows out from a friendly edge with 2 free cells on the first row below the play is equivalent to playing at all three cells simultaneously, and hence at least as good as playing at either cell on the first row. So as a rule, one should never play on the first row in such a situation. We can see this by viewing the 3 upper red stones as part of a friendly edge.

This pattern, along with Example 4, can be used to show that the 2-move opening a1 + b1 (or either single move) for Red loses on a board 3x3 or bigger:

Example 5b (Opening A1+B1 loses)

abc1234
and
abc1234

In response to a1+b1 by Red, Blue can play at b2. This captures a2 and a3 by Example 5, and then a1 and b1 by applying Example 1 twice. Thus, the left position is equivalent to the right one. This includes the cells a1 and a2, so the original position is losing for Red by a strategy stealing argument.

In fact, making the opening play b2 is equivalent to playing 5 stones at a1, a2, b1, b1, and c1. However this is known to produce a losing position on boards of size 4, 7 & 8 (see small boards).

This example also shows that the opening moves a1 and b1 should never be swapped. Playing at b2 is always at least as good for Blue as swapping (but there are even better moves for Blue available elsewhere on the board).

Example 6

and

Example 7

and

Using both rules together:

Example 8

and

Example 9

(generalization of the Example 5, for any horizontal length)

and

Here is a third (rather obvious) rule for equivalent patterns: Any area surrounded by a single chain of the opponent may be randomly filled. This happens because the outcome of the game does not depend on it at all.

Equivalence for reasons other than capture

Capture is not the only way in which equivalent patterns arise. The following is an example of this.

Example 10

The following two patterns are equivalent:

a
and
a

This is easily seen by noticing that if the cells marked "a" are both blue, the patterns become equal, whereas if the cells marked "a" are both red, then the blue piece next to each of them may as well be red by Examples 1 and 3, respectively, so the patterns are equivalent. So whenever one player's strategy calls for playing in the cell marked "a" in one of these two patterns, the same player can play in the cell marked "a" in the other pattern.

Practical examples

First example game

Let us see a practical example. In game #206040 at Little Golem, the situation after 55. m2 is shown in the board below.

abcdefghijklm12345678910111213

Clearly, m2 is strongly connected to the top, because the stone in f4 is a ladder escape. On the other hand, it is strongly connected to the bottom exactly if blue cannot connect k3 with the right, using j6 and maybe the group in h8-h9-f10 as a ladder escape. In fact he cannot do it, and it is much clearer if some patterns are locally replaced by other equivalent ones, rendering:

abcdefghijklm12345678910111213

The changes have been:

  • f6 and h5 swap color, as in Example 1.
  • The blue group from d8 to l11 is completely wrapped by a strongly connected group belonging to the opponent, except for a narrow section (typically, 2 cells). This kind of groups typically are captured, exactly in the same reason as in Example 1.
  • If blue moves to i7, red moves to i9 and conversely, in both cases enclosing the blue group h8-h9-f10 as before. So, we can use the second rule for detecting equivalent patterns, capturing it.
  • The equivalence in Example 5 can be used for the stone in c12.
  • The equivalence in Example 4 can be used, adding a stone for Red at m11.
  • The area in the bottom of the board is now surrounded by a red chain and a blue chain. Therefore, it may be filled as we please.

The blue stone in j6 remained, completely alone and too near to the red group to be of any use in such a small region, so it is obvious that Red has won.

Second example game

In the following game, Red's c9 is connected to the top edge via edge template V-2a. A 3rd row ladder is about to form along the bottom edge. Red wonders whether his other stones are enough to escape the ladder.

abcdefghijk1234567891011

The analysis of this position seems complicated at first. It can be simplified by using the equivalence in Example 10 to shift the blue stone from f6 to e6.

abcdefghijk1234567891011

The key observation is that the single stone i6 on the 6th row is enough for a 3rd-to-6th row switchback (see B6 switchback) or even for a 3rd-to-5th row switchback (see C6 switchback). The resulting ladder is then escaped by g6 via interior ziggurat. Specifically, if Red pushes the ladder all the way to g9, the red stone at g6 will be connected to this ladder by an interior ziggurat:

abcdefghijk123456789101113572468

Now Red can play the 3rd-to-6th row switchback by breaking the ladder and playing one more piece. Note how i6 becomes the ladder stone for a 3rd row ladder in the opposite direction, which the ziggurat escapes. Therefore, Red is connected.

abcdefghijk123456789101111109

One may wonder whether it would have helped Blue to yield to a 2nd row ladder. This would not have helped here. For example:

abcdefghijk123456789101113135121124710986

This time, Black's 13 acts as a ladder stone for a 2nd row ladder stone in the opposite direction, which the ziggurat again escapes.