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737:{\displaystyle \exists S_{1}\exists S_{2}\exists S_{3}\,\forall u\forall v\,{\bigl (}S_{1}(u)\vee S_{2}(u)\vee S_{3}(u){\bigr )}\,\wedge \,{\bigl (}E(u,v)\,\implies \,(\neg S_{1}(u)\vee \neg S_{1}(v))\,\wedge \,\left(\neg S_{2}(u)\vee \neg S_{2}(v)\right)\,\wedge \,(\neg S_{3}(u)\vee \neg S_{3}(v)){\bigr )}}
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is a quantifier-free formula: any boolean combination of the relations. That is, only existential second-order quantification (over relations) is allowed and only universal first-order quantification (over vertices) is allowed. If existential quantification over vertices were also allowed, the
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243:{\displaystyle \exists S_{1}\dots \exists S_{\ell }\,\forall v_{1}\dots \forall v_{m}\,\phi (R_{1},\dots ,R_{k},S_{1},\dots ,S_{\ell },v_{1},\dots ,v_{m})}
1068:{\displaystyle \max \limits _{S_{1},\dots ,S_{\ell }}|\{(v_{1},\dots ,v_{m})\colon \phi (R_{1},\dots ,R_{k},S_{1},\dots ,S_{\ell },v_{1},\dots ,v_{m})\}|}
366:
resulting complexity class would be equal to NP (more precisely, the class of those properties of relational structures that are in NP), a fact known as
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20:
1244:
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and at most 3 literals per clause), find an assignment satisfying as many clauses as possible. In fact, it is a natural
61:
1419:
1282:
Papadimitriou, Christos H.; Yannakakis, Mihalis (1991). "Optimization, approximation, and complexity classes".
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is defined as the class of optimization problems on relational structures expressible in the following form:
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correspond to sets of vertices colored with one of the 3 colors. Similarly, SNP contains the
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32:
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1303:
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Feder, Tomás; Vardi, Moshe Y. (1993). "Monotone monadic SNP and constraint satisfaction".
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For example, SNP contains 3-Coloring (the problem of determining whether a given graph is
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tuples, one wants to maximize the number of tuples for which it is satisfied. That is,
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Proceedings of the twenty-fifth annual ACM symposium on Theory of computing - STOC '93
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denotes the adjacency relation of the input graph, while the sets (unary relations)
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are relations of the structure (such as the adjacency relation, for a graph),
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1184:-complete (under PTAS reductions), and hence does not admit a PTAS unless
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1336:. Texts in Theoretical Computer Science. An EATCS Series. Berlin:
45:
properties. It forms the basis for the definition of the class
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56:
It is defined as the class of problems that are properties of
377:), because it can be expressed by the following formula:
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are unknown relations (sets of tuples of vertices), and
852:, when instead of asking a formula to be satisfied for
1156:(slightly more general than L-reductions) is equal to
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is then defined as the class of all problems with an
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1188:. However, the proof of this relies on the
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1332:Finite model theory and its applications
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1111:: given an instance of 3-CNF-SAT (the
338:{\displaystyle S_{1},\dots ,S_{\ell }}
1316:Grädel, Erich; Kolaitis, Phokion G.;
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292:{\displaystyle R_{1},\dots ,R_{k}}
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813:{\displaystyle S_{1},S_{2},S_{3}}
68:formula of the following form:
35:containing a limited subset of
21:computational complexity theory
1113:boolean satisfiability problem
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1267:: CS1 maint: date and year (
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1160:; that is, every problem in
1168:to it from some problem in
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836:literals per clause, where
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1134:to solve any problem in
1172:. In particular, every
1132:approximation algorithm
1130:There is a fixed-ratio
1117:conjunctive normal form
830:conjunctive normal form
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358:{\displaystyle \phi }
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58:relational structures
51:optimization problems
1284:J. Comput. Syst. Sci
1229:. pp. 612–622.
1115:with the formula in
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1091:log-space reduction
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66:second-order logic
1351:978-3-540-00428-8
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1397:Complexity Zoo
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1386:Complexity Zoo
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1375:Complexity Zoo
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1368:External links
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1318:Libkin, Leonid
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1290:(3): 425–440.
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1190:PCP theorem
1083:L-reduction
375:3-colorable
1360:1133.03001
1340:. p.
1304:0765.68036
1246:0897915917
1212:References
1180:) is also
840:is fixed.
1263:cite book
1039:…
1018:ℓ
1007:…
975:…
956:ϕ
953::
934:…
903:ℓ
892:…
703:¬
700:∨
678:¬
671:∧
643:¬
640:∨
618:¬
609:∧
583:¬
580:∨
558:¬
550:⟹
519:∧
489:∨
467:∨
434:∀
428:∀
414:∃
401:∃
388:∃
353:ϕ
331:ℓ
320:…
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190:…
158:…
139:ϕ
125:∀
122:…
109:∀
103:ℓ
95:∃
92:…
79:∃
60:(such as
29:Strict NP
1414:Category
1200:See also
1138:, hence
1121:complete
1102:MAX-3SAT
1255:9229294
31:) is a
1402:MaxSNP
1391:MaxSNP
1358:
1348:
1302:
1253:
1243:
1194:MaxSNP
1174:MaxSNP
1170:MaxSNP
1164:has a
1152:under
1150:MaxSNP
1140:MaxSNP
1136:MaxSNP
1125:MaxSNP
1106:MaxSNP
1095:MaxSNP
1089:, not
1079:MaxSNP
858:MaxSNP
844:MaxSNP
253:where
62:graphs
47:MaxSNP
27:(from
1251:S2CID
747:Here
1346:ISBN
1269:link
1241:ISBN
1186:P=NP
1380:SNP
1356:Zbl
1342:350
1300:Zbl
1292:doi
1231:doi
1206:APX
1182:APX
1162:APX
1158:APX
1145:APX
875:max
854:all
49:of
25:SNP
19:In
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