Search: subworld:everything
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| BP994 |
| Net corresponds to a solid that can tessellate 3D space vs. net does not correspond to a solid that can tessellate 3D space. |
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COMMENTS
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More specifically these solids are polyhedra, and are often called "space-filling".
There is ambiguity here regarding some nets that can be folded to make multiple different solids. For example EX8175 could correspond to a cuboid with a pyramid-like protrusion at each end, a protrusion at one end and an indent at the other, or 2 indents. Only the second of these options can tessellate 3D space. For clarity's sake examples like this are not sorted on either side. |
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CROSSREFS
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Adjacent-numbered pages:
BP989 BP990 BP991 BP992 BP993 * BP995 BP996 BP997 BP998 BP999
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KEYWORD
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stub, precise, 3d, perfect, preciseworld
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CONCEPT
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3d_net (info | search),
3d_solid (info | search)
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WORLD
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polyhedron_net [smaller | same | bigger]
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AUTHOR
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Leo Crabbe
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| BP996 |
| Net corresponds to a convex solid vs. net corresponds to a concave solid. |
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| BP997 |
| There exists a loop that passes through every white square once without passing through the black square vs. there exists no such loop. |
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| BP998 |
| X "X _" vs. all are "X _"; X Y. |
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COMMENTS
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Right:
All are "all but one are ___"; all but one are black.
All are "every other is ___"; every other is solid polygons.
All are "gradually becoming ___"; gradually becoming thickly outlined.
Left:
All but one are "all but one are ___".
Every other is "every other is ___".
Gradually becoming "gradually becoming ___".
Here is another way of putting it:
Call it "meta" when the whole imitates its parts, and call it "doubly-meta" when the whole imitates its parts with respect to the way it imitates its parts. Left are doubly-meta, while right are just meta.
Here is a more belabored way of putting it:
Call something like "is star-shaped" a "rule". An object can satisfy a rule.
Call something like "all but one are ___" a "rule-parametrized rule". A collection of objects can satisfy a rule-parametrized rule with respect to a particular rule.
On the right: every collection fits the same rule-parametrized rule (with respect to various rules); furthermore the collection of collections fits that same rule-parametrized rule (with respect to some unrelated rule that collections can satisfy).
On the left: The collection of collections fits a rule-parametrized rule with respect to the rule of fitting that rule-parametrized rule (with respect to various rules).
Previously, an unintended solution to this BP was "not all groups share some noticeable property vs. all do." It is hard to come up with examples foiling this alternative solution because the rule-parametrized rule (see explanation above) usually has to do with not all objects in the collection fitting the rule. (See BP568, which is about BP ideas that are always overridden by a simpler solution.) The example EX10108 "all five are 'all five are ___'" was added, foiling the alternative solution. |
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CROSSREFS
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The right side of this Problem is a subset of BP999left.
Adjacent-numbered pages:
BP993 BP994 BP995 BP996 BP997 * BP999 BP1000 BP1001 BP1002 BP1003
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EXAMPLE
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"Odd one out with respect to what property is the odd one out" would not fit left: even though this example does seem doubly-meta, it is not doubly-meta in the right way. There is no odd one out with respect to the property of having an odd one out.
Similarly, consider "gradual transition with respect to what the gradual transition is between", etc. Instead of having the form "X 'X __' ", this is more like "X [the __ appearing in 'X __']". Examples like these two could make for a different Bongard Problem. |
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KEYWORD
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hard, less, unwordable, challenge, overriddensolution, infodense, contributepairs, funny, rules, miniworlds
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CONCEPT
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self-reference (info | search)
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WORLD
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zoom in right
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AUTHOR
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Aaron David Fairbanks
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| BP999 |
| The collection of collections obeys the same rule as the individual collections vs. it does not. |
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COMMENTS
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Rhetorical question: Where would the collection of left examples of this Bongard Problem be sorted by this Bongard Problem? (The question is whether these examples considered together satisfy the pattern that all the parts do, namely that the whole satisfies the pattern that all the parts do.)
See BP793 and BP1004 for similar paradoxes. |
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CROSSREFS
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See BP1005 for the version about only numerical properties; examples in that BP would be sorted the same way here that they are there.
See BP1003 for a similar idea. Rather than the collection of collections imitating the individual collections, BP1003 is about the total combined collection imitating the individual collections. A picture showing (for example) an odd number of even-numbered groups would be sorted differently by these two BPs.
Also see BP1004, which is likewise about the whole satisfying the same rule as its parts, but there the parts don't themselves have to be collections; there the parts are just plain individual objects. The panels in BP999 (this BP) should be sorted the same way in BP1004.
See BP1002, which is about only visual self-similarity instead of more general conceptual "self-similarity".
Adjacent-numbered pages:
BP994 BP995 BP996 BP997 BP998 * BP1000 BP1001 BP1002 BP1003 BP1004
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KEYWORD
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nice, abstract, creativeexamples, left-narrow, rules, miniworlds
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CONCEPT
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recursion (info | search),
self-reference (info | search)
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WORLD
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[smaller | same | bigger]
zoom in left | zoom in right
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AUTHOR
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Aaron David Fairbanks
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| BP1001 |
| "____ vs. not" Bongard Problem vs. not. |
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| BP1002 |
| Vaguely self-similar (looks like self-similar fractal after one iteration) vs. not so. |
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CROSSREFS
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See BP1004 for a Problem about conceptual self-similarity instead of visual self-similarity.
See BP188 for a similar Problem restricted to shape outlines made of shape outlines.
Adjacent-numbered pages:
BP997 BP998 BP999 BP1000 BP1001 * BP1003 BP1004 BP1005 BP1006 BP1007
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KEYWORD
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easy, nice, fuzzy, abstract, anticomputer, concept, traditional
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CONCEPT
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fractal (info | search),
recursion (info | search),
self-reference (info | search),
similar_shape (info | search),
similar (info | search)
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AUTHOR
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Aaron David Fairbanks
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| BP1003 |
| The combined collection obeys the same rule as the sub-collections vs. not so. |
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COMMENTS
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Since it is most intuitive to imagine spatially squishing together all the collections in the process of combining them into one big collection, avoid rules that involve relative spatial positionings of objects. |
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CROSSREFS
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Contrast BP999, which is very similar. There, when considering the whole picture, the collections are to be treated as individual objects; here, when considering the whole picture, the collections are to be combined into one big collection. A picture showing (for example) an odd number of even-numbered groups would be sorted differently by these two BPs.
Also contrast BP1004, which is about a collection of plain objects obeying the same rule as all the objects (instead of a collection of [collections of objects] obeying the same rule as all the [collections of objects]).
See BP1006 for the version with only number-based properties. All panels in that Bongard Problem fit the same way in this Bongard Problem as well.
Adjacent-numbered pages:
BP998 BP999 BP1000 BP1001 BP1002 * BP1004 BP1005 BP1006 BP1007 BP1008
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KEYWORD
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nice, abstract, notso, creativeexamples, rules, miniworlds
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CONCEPT
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recursion (info | search),
self-reference (info | search)
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WORLD
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[smaller | same | bigger]
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AUTHOR
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Leo Crabbe, Aaron David Fairbanks
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