1999

• Andreas Jakoby, Maciej Liskiewicz, Rüdiger Reischuk:
  Scheduling Dynamic Graphs.
  In 16. GI-MIMD Symposium on Theoretical Aspects of Computer Science STACS'99, Band 1563 von Lecture Notes in Computer Science, S. 383-393. Springer, 1999.
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• Maciej Liskiewicz, Rüdiger Reischuk:
  On Small Space Complexity Classes of Stochastic Turing Machines and Arthur-Merlin-Games.
  Computational Complexity, 3(8):273-307, 1999.
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1998

• Andreas Jakoby, Maciej Liskiewicz, Rüdiger Reischuk:
  Scheduling Dynamic Graphs.
  Technischer Bericht SIIM-TR-A-98-07, Schriftenreihe der Institute für Informatik/Mathematik der Universität zu Lübeck, 1998.
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  In parallel and distributed computing scheduling low level tasks on the available hardware is a fundamental problem. Traditionally, one has assumed that the set of tasks to be executed is known beforehand. Then the scheduling constraints are given by a precedence graph. Nodes represent the elementary tasks and edges the dependencies among tasks. This static approach is not appropriate in situations where the set of tasks is not known exactly in advance, for example, when different options how to continue a program may be granted. In this paper a new model for parallel and distributed programs, the dynamic process graph will be introduced, which represents all possible executions of a program in a compact way. The size of this representation is small -- in many cases only logarithmically with respect to the size of any execution. An important feature of our model is that unlike precedence graphs, the encoded executions are directed acyclic graphs having a "regular" structure that is typical of parallel programs. Dynamic process graphs embed constructors for parallel programs, synchronization mechanisms as well as conditional branches. With respect to such a compact representation we investigate the complexity of different aspects of the scheduling problem: the question whether a legal schedule exists at all and how to find an optimal schedule. Our analysis takes into account communication delays between processors exchanging data. Precise characterization of the computational complexity of various variants of this compact scheduling problem will be given in this paper. The results range from easy, that is NL-complete, to very hard, namely NEXPTIME-complete.

1997

• Maciej Liskiewicz, Rüdiger Reischuk:
  Computational Limitations of Stochastic Turing Machines and Arthur-Merlin Games with Small Space Bounds.
  In 22. Int. Symposium on Mathematical Foundations of Computer Science MFCS'97, Band 1295 von Lecture Notes in Computer Science, S. 91-107. Springer, 1997.
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• Maciej Liskiewicz:
  Interactive Proof Systems with Public Coin: Lower Space Bounds and Hierarchies of Complexity Classes.
  In Proc. 14th Symposium on Theoretical Aspects of Computer Science (STACS 1997), Band 1200 von Lecture Notes in Computer Science, S. 129-140. Springer, 1997.
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• Rüdiger Reischuk, Maciej Liskiewicz:
  Computing with Sublogarithmic Space.
  In Complexity Theory Respective II, S. 197-224. Springer, 1997.
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1996

• Maciej Liskiewicz, Rüdiger Reischuk:
  Separating Small Space Complexity Classes of Stochastic Turing Machines.
  Technischer Bericht SIIM-TR-A-96-17, Schriftenreihe der Institute für Informatik/Mathematik der Universität zu Lübeck, 1996.
  Postscript anzeigen | Zusammenfassung anzeigen
  
  Stochastic Turing machines are Turing machines that can perform nondeterministic and probabilistic moves. Such devices are also called games against nature, Arthur-Merlin games, or interactive proof systems with public coins. We investigate stochastic machines with space ressources between constant and logarithmic size and constant or sublinear bounds on the number of alternations between nondeterministic and probabilistic moves. Separation results are proven for the corresponding complexity classes by showing the inclusion, resp.~noninclusion of certain languages. The lower bounds hold without any restriction on the run time and will follow from more general combinatorial properties. These results imply an infinite hierarchy with linear distance based on the number of alternations. The separations are obtained by extending and improving lower bound techniques developed for probabilistic automata and stochastic machines by which previously the lower levels have been separated, resp.~a hierarchy with exponential distance has been shown. Furthermore, we establish a hierarchy for stochastic Turing machines with arbitrary small nonconstant space bounds. COMMENTS: extends Technical Report A-96-08
• Maciej Liskiewicz, Rüdiger Reischuk:
  Space Bounds for Interactive Proof Systems with Public Coins and Bounded Number of Rounds.
  Technischer Bericht SIIM-TR-A-96-08, Schriftenreihe der Institute für Informatik/Mathematik der Universität zu Lübeck, 1996.
  Postscript anzeigen | Zusammenfassung anzeigen
  
  This paper studies interactive proofs, resp. Arthur-Merlin games with a sublogarithmic space-bounded verifier. We provide examples of specific languages and show that such systems are unable to accept these languages. As a consequence, a new separation is obtained for the complexity classes on the second level of the round/alternation hierarchy.
• Maciej Liskiewicz, Rüdiger Reischuk:
  The Sublogarithmic Alternating Space World.
  SIAM Journal on Computing, 4(25):828-861, 1996.
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1995

• Maciej Liskiewicz:
  On the power of 1-tape off-line ATMs running in a bounded number of reversals.
  Mathematical Systems Theory, 28:329-339, 1995.
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• Maciej Liskiewicz, Rüdiger Reischuk:
  The Complexity World below Logarithmic Space.
  Technischer Bericht SIIM-TR-A-95-07, Schriftenreihe der Institute für Informatik/Mathematik der Universität zu Lübeck, 1995.
  Postscript anzeigen | Zusammenfassung anzeigen
  
  We investigate space complexity classes defined by Turing machines that use less than logarithmic space. Because of the limited counting ability of such machines most of the standard simulation techniques do not work for sublogarithmic space classes. However, machines with such little space may still be quite powerful. Therefore, it was not obvious how to obtain analogs for inclusion and separation results known for classes above logspace. We review known facts about the sublogarithmic space world and present several new results, which show that these classes really behave differently. For example, certain closure properties do not hold. The restricted power of these machines makes it possible to prove explicit separations -- even for alternating complexity classes -- by combinatorial arguments and to obtain a hierarchy of non-relativized complexity classes without any unproven assumption. We will also discuss upward and downward translation issues. Finally, these complexity classes are related to other classes within P, in particular to context-free languages.
• Maciej Liskiewicz, Rüdiger Reischuk:
  The Sublogarithmic Alternating Space World.
  Technischer Bericht SIIM-TR-A-95-01, Schriftenreihe der Institute für Informatik/Mathematik der Universität zu Lübeck, 1995.
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  This paper tries to fully characterize the properties and relationships of space classes defined by Turing machines that use less than logarithmic space -- may they be deterministic, nondeterministic or alternating (DTM, NTM or ATM). We provide several examples of specific languages and show that such machines are unable to accept these languages. The basic proof method is a nontrivial extension of the 1^n -> 1^{n+n!} technique to alternating TMs. Let \llog denote the logarithmic function \log iterated twice, and Sigma_k Space(S), Pi_k Space (S) be the complexity classes defined by S-space-bounded ATMs that alternate at most k-1 times and start in an existential, resp.~universal state. Our first result shows that for each k > 1 the sets Sigma_k Space(llog) \ Pi_k Space (o(log)) and Pi_k Space(llog) \ Sigma_k Space (o(log)) are both not empty. This implies that for each S in the intersection of Omega(llog) and o(log ) Sigma_1 Space(S), Sigma_2 Space(S), Sigma_3 Space(S) .. .. form an infinite hierarchy. Furthermore, this separation is extended to space classes defined by ATMs with a nonconstant alternation bound A provided that the product A * S grows sublogarithmically. These lower bounds can also be used to show that basic closure properties do not hold for such classes. We obtain that for any S in Omega(llog) intersection o(log) and all k>1 \Sigma_k Space (S) and \Pi_k Space (S) are not closed under complementation and concatenation. Moreover, \Sigma_k Space (S) is not closed under intersection, and \Pi_k Space (S) is not closed under union. It is also shown that ATMs recognizing bounded languages can always be guaranteed to halt. For the class of Z--bounded languages with Z <= \exp S we obtain the equality co-Sigma_k Space(S) = Pi_k Space (S) . Finally, for sublogarithmic bounded ATMs we give a separation between the weak and strong space measure, and prove a logarithmic lower space bound for the recognition of nonregular context-free languages. Key words: space complexity, sublogarithmic complexity bounds, alternating Turing machines, halting computations, complementation of languages, complexity hierachies, closure properties, context-free languages, bounded languages. AMS(MOS) subject classifications: 68Q05, 68Q10, 68Q25, 68Q45 Preliminary versions of these results have been presented at the 10. GI-AFCET Symposium on Theoretical Aspects of Computer Science, W"urzburg, 1993, and at the 9. IEEE-SIGACT-EATCS Symposium on Structure in Complexity Theory, Amsterdam, 1994. A final version will appear in SIAM Journal on Computing.

1994

• Maciej Liskiewicz, Rüdiger Reischuk:
  The Complexity World below Logarithmic Space.
  In 9. Ann. IEEE - SIGACT - EATCS Symposium on Structure in Complexity Theory STRUCTURES'94, S. 64-78. IEEE Computer Society, 1994.

1993

• Maciej Liskiewicz:
  On the relationship between deterministic time and deterministic reversal.
  Information Processing Letters, 45(3):143-146, 1993.
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• Maciej Liskiewicz, Rüdiger Reischuk:
  Separating the Lower Levels of the Sublogarithmic Space Hierarchy.
  In 10. GI-AFCET Symposium on Theoretical Aspects of Computer Science STACS'93, Band 665 von Lecture Notes in Computer Science, S. 16-27. Springer, 1993.
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1990

• Miroslaw Kutylowski, Maciej Liskiewicz, Krzysztof Lorys:
  Reversal complexity classes for alternating Turing machines.
  SIAM Journal on Computing, 19(2):207-221, 1990.
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• Maciej Liskiewicz, Krzysztof Lorys:
  Fast simulations of time-bounded one-tape Turing machines by space-bounded ones.
  SIAM Journal on Computing, 19(3):511-521, 1990.
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