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Earl
Joined: 30 May 2007 Posts: 677 Location: Victoria, KS
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Posted: Mon May 12, 2008 1:43 pm Post subject: Multi-task |
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A multi-task puzzle. I could not find a single step solution.
Earl
Code: |
+-------+-------+-------+
| . . . | . . . | . 2 6 |
| 4 7 3 | . . . | . 5 . |
| 2 . . | . . . | . . 7 |
+-------+-------+-------+
| . 5 . | . 3 6 | . . . |
| 3 . . | . . . | . 6 . |
| . . . | 7 4 8 | . 3 . |
+-------+-------+-------+
| . . 4 | . 1 . | . . . |
| . . 6 | 4 . . | 8 . 2 |
| 1 . . | 6 . 7 | . . 5 |
+-------+-------+-------+
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Play this puzzle online at the Daily Sudoku site |
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Asellus
Joined: 05 Jun 2007 Posts: 865 Location: Sonoma County, CA, USA
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Posted: Mon May 12, 2008 8:49 pm Post subject: |
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I found a 3-step path. Anyone come up with something shorter? |
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storm_norm
Joined: 18 Oct 2007 Posts: 1741
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Posted: Tue May 13, 2008 1:51 am Post subject: |
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Asellus wrote: | I found a 3-step path. Anyone come up with something shorter? |
I am thinking either the 8,9 pairs or the 2,8 pairs, but I can't find more than a couple eliminations on both.
the xy-wing is powerful to start, but it does nothing for the 8,9 pairs and any w-wing, m-wing's, you still need another step after that. |
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Marty R.
Joined: 12 Feb 2006 Posts: 5770 Location: Rochester, NY, USA
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Posted: Tue May 13, 2008 5:03 am Post subject: |
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Thanks Earl, I had fun with that one.
XY (seemed useless)
Two ERs
XY with pincer coloring
XY
At this point there was a BUG+1 pattern, but I finished it off with another XY. |
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Asellus
Joined: 05 Jun 2007 Posts: 865 Location: Sonoma County, CA, USA
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Posted: Tue May 13, 2008 5:15 am Post subject: |
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One of my steps is a not often used technique present in boxes 4 and 7. See if anyone can spot it.
The other is a Skyscraper which is present from the beginning and independent of the first step.
These two result in a BUG+1. |
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storm_norm
Joined: 18 Oct 2007 Posts: 1741
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Posted: Tue May 13, 2008 6:46 am Post subject: |
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Code: | .---------------------.---------------------.---------------------.
|%89 1-8 1589 | 13589 7 1459 | 1349 2 6 |
| 4 7 3 | 1289 6 129 | 19 5 89 |
| 2 6 1589 | 13589 *89 1459 | 1349 #489 7 |
:---------------------+---------------------+---------------------:
|*89 5 17 | 12 3 6 | 27 #89 4 |
| 3 4 #178 | 1259 $29 1259 | 27 6 #18 |
| 6 12 129 | 7 4 8 | 5 3 19 |
:---------------------+---------------------+---------------------:
| 5 2%8 4 | 289 1 29 | 6 7 3 |
| 7 9 6 | 4 5 3 | 8 1 2 |
| 1 3 $28 | 6 $28 7 | 49 49 5 |
'---------------------'---------------------'---------------------' |
this is the most powerful first move I could come up with.
this grid exploits the {8,9} extended W-wing ( Ravel's Kite extension as seen in a previous post)
# = marks the kite and that in itself eliminates the 8 in r3c3.
* = marks the {8,9} pair connected by the kite
% = marks the 8's that must be true on each end of the chain
$ = marks the coloring you can accomplish on one end of the W-wing.
on one end of the extended W-wing you can color up to the 8 in r1c1
on the other end you can color down and over to the 8 in r7c2..
all this just to prove that either 8's are true.
this eliminates the 8 in r1c2
I might need help with this notation
its a long one
(8)r1c1=(9)r1c1=(9)r4c1=(8)r4c1=(8)r5c3=(8)r5c9=(8)r4c8=(8)r3c8-(8)r3c5=(9)r3c5=(9)r5c5=(2)r5c5=(2)r9c5=(8)r9c5=(8)r9c3=(8)r7c2 => r1c2<>8
that elimination along with the 8 gone in r3c3
leaves you with this BUG, 4 goes in r3c7
Code: | .---------------.---------------.---------------.
| 89 1 89 | 35 7 45 | 34 2 6 |
| 4 7 3 | 28 6 12 | 19 5 89 |
| 2 6 5 | 38 9 14 | 134 48 7 |
:---------------+---------------+---------------:
| 89 5 7 | 1 3 6 | 2 89 4 |
| 3 4 18 | 59 2 59 | 7 6 18 |
| 6 2 19 | 7 4 8 | 5 3 19 |
:---------------+---------------+---------------:
| 5 8 4 | 29 1 29 | 6 7 3 |
| 7 9 6 | 4 5 3 | 8 1 2 |
| 1 3 2 | 6 8 7 | 49 49 5 |
'---------------'---------------'---------------' |
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tlanglet
Joined: 17 Oct 2007 Posts: 2468 Location: Northern California Foothills
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Posted: Tue May 13, 2008 12:43 pm Post subject: |
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The best I have achieved is to use multi-coloring on <8> which eliminates several cells and after more basics, an xy-wing on <348> with pivot at r3c8 deleting the <3> at r1c4 finished it off.
Ted |
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tlanglet
Joined: 17 Oct 2007 Posts: 2468 Location: Northern California Foothills
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Posted: Tue May 13, 2008 12:59 pm Post subject: |
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Norm,
I believe that we did very similar operations on <8>. You used extensions to a kite and I used multi-coloring. The <348> xy-wing I used to complete the puzzle is evident in your code after the kite eliminations.
Ted |
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storm_norm
Joined: 18 Oct 2007 Posts: 1741
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Posted: Tue May 13, 2008 6:54 pm Post subject: |
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tlanglet wrote: | Norm,
I believe that we did very similar operations on <8>. You used extensions to a kite and I used multi-coloring. The <348> xy-wing I used to complete the puzzle is evident in your code after the kite eliminations.
Ted |
yes, I see the xy-wing, there is also a xyz-wing in box 3 on {1,3,4}
Asellus wrote
Quote: | One of my steps is a not often used technique present in boxes 4 and 7. See if anyone can spot it.
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Human sized, long arms, hairy, King Kong comes to mind.
there is someone who normally posts in the daily threads that probably would have spotted this. from what I read in previous posts, he/she was good at spotting them. forget who it was.
that elimination of that 2 is very powerful.
the direct implications of that elimination results in 11 solved cells.
the elimination of the 8 from r1c2 in my convolution solves 11 directly also. |
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Asellus
Joined: 05 Jun 2007 Posts: 865 Location: Sonoma County, CA, USA
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Posted: Tue May 13, 2008 9:21 pm Post subject: |
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Norm wrote: | Human sized, long arms, hairy, King Kong comes to mind. |
Hah! I wasn't thinking of APE, but you are quite correct. I was thinking ALS: r6c2 and r459c3; shared exclusive <1>; shared common <2> eliminates that same <2> in r6c3. (Once again, Keith's assertion that an APE may never be "necessary" is born out.)
I looooonnnnnggg ago posted somewhere that it would be possible to use two-cluster multi-coloring from the non-pincer digits of a W-Wing and hoped to see someone post an example. And, at long last, here it is... sort of.
I say "sort of" because this W-Wing only has a single weak link, the 8-8 in r3. So, as others have pointed out, this is just a two-cluster <8> multi-coloring and the W-Wing part (and the chain detour to those <9>s and <2> ... including them makes it Medusa multi-coloring by the way) isn't necessary. Had there been more than one weak link in the W-Wing, then the multi-coloring would have involved 3 (or more) clusters. For those not comfortable with more than 2 clusters, seeing the W-Wing and 2-cluster option might be helpful in such cases.
Norm, the only "quibble" I have with your notation is that you are using "=" to mean conjugate link rather than strong inference. That's fine if it's understood that way. But, I believe it is more useful to alternate the symbols according to the inferences so that the strong links on the pincer ends of the chain are obvious without having to "count links." (It's too bad we don't have a different symbol for when we want to notate conjugate links.) |
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storm_norm
Joined: 18 Oct 2007 Posts: 1741
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Posted: Tue May 13, 2008 10:45 pm Post subject: |
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Quote: | I looooonnnnnggg ago posted somewhere that it would be possible to use two-cluster multi-coloring from the non-pincer digits of a W-Wing and hoped to see someone post an example. And, at long last, here it is... sort of. |
Asellus, you have been on the medusa multicoloring train for a long time. that influence as well as Ravel's examples of extending the useless Kites was my inspiration for these patterns. I pondered this puzzle til I was blue in the face and couldn't get a more dominant chain. I didn't see the elimination of the 2 in box 4. wish I would have.
Quote: | Norm, the only "quibble" I have with your notation is that you are using "=" to mean conjugate link rather than strong inference |
to be quite honest, I have no idea what I am doing when it comes to notation. so it seems the only way I am going to learn is to just go for it and have the corrections teach me. so how would I write it better? or what should the notation be? I would love to figure this out.
part of the reason I am a little in the dark is because I really never study chain notation. and I have seen two different types of chain notation, so its kind of confusing why there would be two types in the first place. |
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cathyv
Joined: 25 Apr 2008 Posts: 7 Location: Danbury, CT
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Posted: Tue May 13, 2008 11:17 pm Post subject: |
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Help please - I got this far and can trace the 89 pair marked with * in the post above, but you guys lost me with how you extended it from there. I'm learning...but these APEs and ALSs and long chains are still a struggle. Thanks!
Code: |
+------------+---------------+-------------+
| 89 18 1589 | 1359 7 145 | 1349 2 6 |
| 4 7 3 | 1289 6 12 | 19 5 89 |
| 2 6 159 | 13589 *89 145 | 1349 489 7 |
+------------+---------------+-------------+
| *89 5 17 | 12 3 6 | 27 89 4 |
| 3 4 178 | 1259 29 1259 | 27 6 18 |
| 6 12 129 | 7 4 8 | 5 3 19 |
+------------+---------------+-------------+
| 5 28 4 | 289 1 29 | 6 7 3 |
| 7 9 6 | 4 5 3 | 8 1 2 |
| 1 3 28 | 6 28 7 | 49 49 5 |
+------------+---------------+-------------+
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storm_norm
Joined: 18 Oct 2007 Posts: 1741
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Posted: Wed May 14, 2008 1:56 am Post subject: |
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cathyv, hello.
in the above image is my chain, its a long, long, long chain to try and get a grip on. its like jumping into the deep end of the W-wing pool.
the green line is the Kite on the number 8 (as you said you figured out).
When you have this kite that "sees" both {8,9}'s in r4c1 and r5c5, all this means is that either 9 is true ( in r4c1 and r5c5 )
with this knowlegde, you can "extend" A.K.A. "color" those 9's.
first is the "blue" lines
the 9 in r4c1, if that 9 is true, that means,
that the 9 in r1c1 is not true
this means that the 8 in r1c1 is true... remember that...
next is the red lines
xx over to the 9 in r3c5, if that 9 is true
leads to r5c5 is not 9
" r5c5 is 2
" r9c5 is not 2, r9c5 is 8
" r9c3 is not 8, r9c3 is 2
" r7c2 is not 2, r7c2 is 8, so this 8 is true.
now we have the same situation as we did with the original 9's. both the 8 in r7c2 and r1c1 can be true, thus we can eliminate the 8 in r1c2.
note: you don't need this "overkill" move to continue solving this puzzle from your posted position. if you understand xy-chains and xy-wings, then I think 2 or 3 xy-chains should do the trick.
also, the challenge was made to solve it in less than 3 moves which prompted this type of chain. I was trying to "nuke" it. |
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Asellus
Joined: 05 Jun 2007 Posts: 865 Location: Sonoma County, CA, USA
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Posted: Wed May 14, 2008 10:07 am Post subject: |
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Hi cathyv,
Norm's chain is an interesting creation. But, if it is bewildering you, then perhaps you'd prefer to look at coloring of <8>s. Let's start with basic coloring. Perhaps you are familiar with the technique already. But, just in case, here is what I've done: I've marked a sequence of end-to-end conjugate pairs of <8>s in the grid using "A" and "a" to label the opposite pairs, or "polarity". A conjugate link or conjugate pair (also commonly called a strong link) is an "either/or" relationship: one must be true and one must be false. This is the case when there are only two instances of a particular candidate digit within a house (row, column or box).
Code: | +-----------------+------------------+-----------------+
| 8A9 18 1589 |#135-89 7 1459 | 1349 2 6 |
| 4 7 3 | 128a9 6 129 | 19 5 8A9 |
| 2 6 #15-89 | 13589 89 1459 | 1349 48a9 7 |
+-----------------+------------------+-----------------+
| 8a9 5 17 | 12 3 6 | 27 8A9 4 |
| 3 4 178A | 1259 29 1259 | 27 6 18a |
| 6 12 129 | 7 4 8 | 5 3 19 |
+-----------------+------------------+-----------------+
| 5 28 4 | 289 1 29 | 6 7 3 |
| 7 9 6 | 4 5 3 | 8 1 2 |
| 1 3 28 | 6 28 7 | 49 49 5 |
+-----------------+------------------+-----------------+ |
It should be easy to see that either all of the "8A"s are true or all of the "8a"s are true... we just don't know which. But, any <8> that can "see" both an 8A and an 8a cannot be true since one of these will be true. We have 2 such <8>s, in the cells marked #, so we can remove them.
(Note: The elimination of the <8> in r3c3 can also be seen as due to the Skyscraper in columns 1 and 8. And, once this <8> is gone, the <8> in r1c4 is removed by the "Locked Candidates" in r1 or box 1.)
Now, I'm going to move up a level in coloring and mark a second cluster of conjugate <8>s, this time using "B" and "b":
Code: | +-----------------+------------------+-----------------+
| 8A9 #18b 1589 | 1359 7 1459 | 1349 2 6 |
| 4 7 3 | 128a9 6 129 | 19 5 8A9 |
| 2 6 159 | 13589 8b9 1459 | 1349 48a9 7 |
+-----------------+------------------+-----------------+
| 8a9 5 17 | 12 3 6 | 27 8A9 4 |
| 3 4 178A | 1259 29 1259 | 27 6 18a |
| 6 12 129 | 7 4 8 | 5 3 19 |
+-----------------+------------------+-----------------+
| 5 28B 4 | 289 1 29 | 6 7 3 |
| 7 9 6 | 4 5 3 | 8 1 2 |
| 1 3 #28b | 6 28B 7 | 49 49 5 |
+-----------------+------------------+-----------------+ |
There are a couple of ways we could look at this. But, I'm going to focus on r3 for a moment. There are 3 <8>s in r3. And, one of them is an "8a" and one is an "8b", so these two "see" each other in r3. They are not conjugate because of the 3 <8>s in the row. So, it is possible that both of them are false. This is called a weak link.
Now, if "8a" is false, all the "8A"s are true. And, if "8b" is false, all the "8B"s are true. And, if BOTH "8a" and "8b" are false, then BOTH the "8A"s and "8B"s are true. So, no matter what, any <8> that can see both "8A" and "8B" (the polarities opposite those of the weakly linked <8>s in r3) cannot be true. This is called "Multi-Coloring" or, sometimes, a "Color Wing." There are two such eliminations, in the cells marked #.
And...
As long as we're at it, let's look at that ALS option. ALS stands for Almost Locked Set. This is situation where n+1 candidates are contained in n cells that are all peers (can all see each other). The smallest ALS is any bivalue cell. It turns out that if there is a special relationship between two different ALSs, then eliminations are possible.
Here's the grid with the ALSs marked, one "A" and one "B":
Code: | +-----------------+------------------+-----------------+
| 89 18 1589 | 13589 7 1459 | 1349 2 6 |
| 4 7 3 | 1289 6 129 | 19 5 89 |
| 2 6 1589 | 13589 89 1459 | 1349 489 7 |
+-----------------+------------------+-----------------+
| 89 5 B17 | 12 3 6 | 27 89 4 |
| 3 4 B178 | 1259 29 1259 | 27 6 18 |
| 6 A12 #1-29 | 7 4 8 | 5 3 19 |
+-----------------+------------------+-----------------+
| 5 #-28 4 | 289 1 29 | 6 7 3 |
| 7 9 6 | 4 5 3 | 8 1 2 |
| 1 3 B28 | 6 28 7 | 49 49 5 |
+-----------------+------------------+-----------------+ |
The "A" ALS is just a {12} bivalue cell. The "B" ALS is {1278} in 3 cells in c3. Now, the "tricky part." There must be a candidate digit common to both ALSs that can only exist in one or the other but not both of them. This is called the "shared exclusive" candidate. Here, it is <1>. If <1> is true in B, then it cannot be in A and vice versa. The other requirement is that there be some other digit common to both of the ALSs. Here, that other digit is <2>. This is the "shared common" candidate. There cannot be a <2> in any cell that can see all of the <2>s in these two ALSs. Our shared common <2>s are in two cells: r6c2 and r9c3. There are 2 <2>s that can see both of these, marked # above. These are eliminated.
The reasoning is similar to that of multi-coloring: The shared exclusive candidate is "weakly linked" between the two ALSs. That is, it can't be true in both ALSs, so it is false in at least one of the ALSs. If "A" does not contain <1>, then it is <2>. If "B" does not contain <1>, then one of its <2>s must be true. (As it happens, there is only one <2> in B. But, since B has 3 cells, there could have been more. It that were so, however, we could only eliminate the <2> at r6c3.) So, either A contains a <2> or B contains a <2> or BOTH A and B contain a <2>.
I'll leave it to you to work out that both XY Wings and XYZ Wings are examples of this more general ALS technique. These eliminations with larger ALSs don't come up that often. But, it can be handy to know about them when they do. |
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Asellus
Joined: 05 Jun 2007 Posts: 865 Location: Sonoma County, CA, USA
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Posted: Wed May 14, 2008 11:13 am Post subject: |
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Norm,
Your notation is very close to Eureka notation. In fact, the only difference that matters is that you aren't alternating the inference symbols. We know that the link between those two <8>s in r3 must be weak, so it must be notated using "-". Then, we could take what you've written and just alternate the symbols:
(8)r1c1=(9)r1c1-(9)r4c1=(8)r4c1-(8)r5c3=(8)r5c9-(8)r4c8=(8)r3c8-(8)r3c5=(9)r3c5-
(9)r5c5=(2)r5c5-(2)r9c5=(8)r9c5-(8)r9c3=(8)r7c2 => r1c2<>8
We now know for sure that there is a strong inference between the <8>s on the ends of the chain without counting links. It is important to realize that conjugate links are both weak and strong. When they are joined up end-to-end in a chain, they still have alternating weak and strong inferences. You can shorten the notation by combining links contained within a single cell into a single set of parentheses:
(8=9)r1c1-(9=8)r4c1-(8)r5c3=(8)r5c9-(8)r4c8=(8)r3c8-(8=9)r3c5-
(9=2)r5c5-(2=8)r9c5-(8)r9c3=(8)r7c2 => r1c2<>8
This would be acceptable Eureka to me. Some prefer to write these in "discontinous loop" form, that is with the victim(s) weakly linked at both the beginning and end of the chain:
(8)r1c2-(8=9)r1c1-(9=8)r4c1-(8)r5c3=(8)r5c9-(8)r4c8=(8)r3c8-(8=9)r3c5-
(9=2)r5c5-(2=8)r9c5-(8)r9c3=(8)r7c2-(8)r1c2; r1c2<>8
I've changed your "implies" symbol, the "=>", to a semicolon. This is what is usually used in Eureka. The victims are at a discontinuity in the loop because the links on both sides of them are weak rather than alternating. This means they must be false. (You can also have a discontinuity where the links on both sides are strong. This causes the entities at the discontinuity to be true. Chains of this sort aren't seen as often.)
From what I have seen, there is some variety in how people notate chains within this general Eureka approach. And, that is fine with me. I understand them even if they aren't notated exactly as I would do it. For example, I use braces to group different candidates together since that's how I have seen it done in several places. Recently, Myth Jellies posted a chain notated with ampersands to accomplish the same thing. (In that case, the groups were only two candidates. I write "{37}" and he writes "3&7". I don't know if he would write {3479} as 3&4&7&9. If so, I prefer the braces!)
So, keeping with that variety... some people shorten chain notation further by combining cell references for links between cells, especially if they are strong links. Here's what I mean using your chain from above:
(8)r1c2-(8=9)r1c1-(9=8)r4c1-(8=8)r5c39-(8=8)r34c8-(8=9)r3c5-
(9=2)r5c5-(2=8)r9c5-(8)r9c3=(8)r7c2-(8)r1c2; r1c2<>8
For an example using groups in braces, I'll write the chain notation for the ALS elimination in this puzzle:
(2)r6c3|r7c2-(2=1)r6c2-({178}=2)r459c3-(2)r6c3|r7c2; r6c3|r7c2<>2
There's another new thing here: the vertical line symbol, "|". It means "and". Here, it joins the cell references for the two victim <2>s. The 1278 ALS is expressed as a {178} Locked Set strongly linked with the "extra candidate" <2>: They can't both be false. (It is important to note that the {178} Locked Set is false as a Locked Set if any one of its digits is false.) Notice then that the <1> from the other ALS (the 12 bivalue) is weakly linked with the {178} Locked Set: They can't both be true.
You don't really need much more than this to do Eureka notation. |
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cgordon
Joined: 04 May 2007 Posts: 769 Location: ontario, canada
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Posted: Wed May 14, 2008 5:04 pm Post subject: |
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I found two ERs on <8> and <1> and an xy wing <289>. But I can't see the two wings mentioned above xy<348> and xyz <134> because I have too many 9's in Box 3. Is a chain or ALS solution the only way to get rid of these 9's? |
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tlanglet
Joined: 17 Oct 2007 Posts: 2468 Location: Northern California Foothills
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Posted: Fri May 16, 2008 1:35 am Post subject: |
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cgordon wrote: | I found two ERs on <8> and <1> and an xy wing <289>. But I can't see the two wings mentioned above xy<348> and xyz <134> because I have too many 9's in Box 3. Is a chain or ALS solution the only way to get rid of these 9's? |
I am not sure exactly what your code is when you are not able to see the xy-wing on <348> or the xyz-wing on <134>. Starting with the code posted by storm_norm, I used coloring on <8>'s to make deletions from r1c24, r3c35, r7c4 and r9c3. After cleaning up some singles and deleting <9> from r1c7 due to the naked pair <89> in r1c13, both wings are visible as shown in the second code status again provided by storm_norm. The pivot for the xy-wing on <348> is at r3c8 with pincers at r3c4 and r1c7 whereas the xyz on <134> has the pivot at r3c7 with pincers at r3c6 and r1c7.
As for the <9>s, the <9>s in r3c78 were deleted when r3c5 became a <9> due to the removal of <8> from that cell by coloring and, as already noted, the <9> in r1c7 was stepped on by the naked <89> pair.
I assume your path with the two ERs and an xy-wing on <289> left you in a different code status.
Sorry I am not of greater help.
Ted |
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cgordon
Joined: 04 May 2007 Posts: 769 Location: ontario, canada
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Posted: Fri May 16, 2008 12:46 pm Post subject: |
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Ted said: Quote: | After cleaning up some singles and deleting <9> from r1c7 due to the naked pair <89> in r1c13 |
Ted: There's the rub ! My grid after basics is the same as Storm Norms so how did you end up with the naked pair <89> in r1c13 ??
Craig |
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tlanglet
Joined: 17 Oct 2007 Posts: 2468 Location: Northern California Foothills
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Posted: Fri May 16, 2008 4:08 pm Post subject: |
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Hi Again Craig,
I could not find my notes, so I solved it again in what I believe is the same manner.
First, I used multi-coloring on <8>. One set, say Blue and Green, has 8 cells; the second set, say Red and Orange, contains 6 cells. One cell in the second set "sees" both colors in the first set and therefore that color must be "false". Given my colors, row 1 contains both a Blue and a Red, and box 2 contains a Green and a Red. I deleted the <8>s in r1c2, r3c5, r7c4 and r9c3.
After cleaning up all the resultant singles, I used normal coloring on <8>, forming a set of 8 cells. Cell r3c3, <58>, sees both colors and the cell is assigned the value <5> after deleting the <8>. This, in turn, deletes the <5> in r1c3 thereby providing the pair of naked <89>s.
Hope this helps ..........
Ted |
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cgordon
Joined: 04 May 2007 Posts: 769 Location: ontario, canada
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Posted: Fri May 16, 2008 5:20 pm Post subject: |
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Thanks Ted: I’m not into colouring – tried it - all those conjugate pairs, multiple peers, parities and synchronization – too much like hard work.
But at least I spell it properly – the Colonial way. |
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