Content deleted Content added
No edit summary |
Citation bot (talk | contribs) Removed URL that duplicated identifier. | Use this bot. Report bugs. | Suggested by Abductive | Category:Analysis of algorithms | #UCB_Category 22/47 |
||
| (90 intermediate revisions by 51 users not shown) | |||
Line 1:
{{redirect|AvgP|other uses|avgp (disambiguation)}}
In [[computational complexity theory]], the '''average-case complexity''' of an [[algorithm]] is the amount of some computational resource (typically time) used by the algorithm, averaged over all possible inputs. It is frequently contrasted with [[worst-case complexity]] which considers the maximal complexity of the algorithm over all possible inputs.
There are three primary motivations for studying average-case complexity.<ref name="gol07">{{Cite journal |last1=Goldreich |first1=Oded |last2=Vadhan |first2=Salil |date=December 2007 |title=Special Issue On Worst-case Versus Average-case Complexity Editors' Foreword |journal=Computational Complexity |language=en |volume=16 |issue=4 |pages=325–330 |doi=10.1007/s00037-007-0232-y |issn=1016-3328|doi-access=free }}</ref> First, although some problems may be intractable in the worst-case, the inputs which elicit this behavior may rarely occur in practice, so the average-case complexity may be a more accurate measure of an algorithm's performance. Second, average-case complexity analysis provides tools and techniques to generate hard instances of problems which can be utilized in areas such as [[cryptography]] and [[derandomization]]. Third, average-case complexity allows discriminating the most efficient algorithm in practice among algorithms of equivalent best case complexity (for instance [[Quicksort#Formal analysis|Quicksort]]).
Average-case analysis requires a notion of an "average" input to an algorithm, which leads to the problem of devising a [[probability distribution]] over inputs. Alternatively, a [[randomized algorithm]] can be used. The analysis of such algorithms leads to the related notion of an '''expected complexity'''.<ref name="clrs"/>{{rp|28}}
==History and background==
The average-case performance of algorithms has been studied since modern notions of computational efficiency were developed in the 1950s. Much of this initial work focused on problems for which worst-case polynomial time algorithms were already known.<ref name="bog06">{{Cite journal |last1=Bogdanov |first1=Andrej |last2=Trevisan |first2=Luca |date=2006 |title=Average-Case Complexity |url=http://www.nowpublishers.com/article/Details/TCS-004 |journal=Foundations and Trends in Theoretical Computer Science |language=en |volume=2 |issue=1 |pages=1–106 |doi=10.1561/0400000004 |issn=1551-305X|url-access=subscription }}</ref> In 1973, [[Donald Knuth]]<ref name="knu73">{{cite book
| last = Knuth | first = Donald | title = [[The Art of Computer Programming]] | volume = 3 | publisher = Addison-Wesley | date = 1973
}}</ref> published Volume 3 of the [[Art of Computer Programming]] which extensively surveys average-case performance of algorithms for problems solvable in worst-case polynomial time, such as sorting and median-finding.
An efficient algorithm for [[NP-complete|{{math|'''NP'''}}-complete]] problems is generally characterized as one which runs in polynomial time for all inputs; this is equivalent to requiring efficient worst-case complexity. However, an algorithm which is inefficient on a "small" number of inputs may still be efficient for "most" inputs that occur in practice. Thus, it is desirable to study the properties of these algorithms where the average-case complexity may differ from the worst-case complexity and find methods to relate the two.
The fundamental notions of average-case complexity were developed by [[Leonid Levin]] in 1986 when he published a one-page paper<ref name="levin86">{{Cite journal |last=Levin |first=Leonid A. |date=February 1986 |title=Average Case Complete Problems |url=http://epubs.siam.org/doi/10.1137/0215020 |journal=SIAM Journal on Computing |language=en |volume=15 |issue=1 |pages=285–286 |doi=10.1137/0215020 |issn=0097-5397|url-access=subscription }}</ref> defining average-case complexity and completeness while giving an example of a complete problem for {{math|'''distNP'''}}, the average-case analogue of [[NP (complexity)|{{math|'''NP'''}}]].
==Definitions==
===Efficient average-case complexity===
The first task is to precisely define what is meant by an algorithm which is efficient "on average". An initial attempt might define an efficient average-case algorithm as one which runs in expected polynomial time over all possible inputs. Such a definition has various shortcomings; in particular, it is not robust to changes in the computational model. For example, suppose algorithm {{mvar|A}} runs in time {{math|''t''<sub>''A''</sub>(''x'')}} on input {{mvar|x}} and algorithm {{mvar|B}} runs in time {{math|''t''<sub>''A''</sub>(''x'')<sup>2</sup>}} on input {{mvar|x}}; that is, {{mvar|B}} is quadratically slower than {{mvar|A}}. Intuitively, any definition of average-case efficiency should capture the idea that {{mvar|A}} is efficient-on-average if and only if {{mvar|B}} is efficient on-average. Suppose, however, that the inputs are drawn randomly from the uniform distribution of strings with length {{mvar|n}}, and that {{mvar|A}} runs in time {{math|''n''<sup>2</sup>}} on all inputs except the string {{math|1<sup>''n''</sup>}} for which {{mvar|A}} takes time {{math|2<sup>''n''</sup>}}. Then it can be easily checked that the expected running time of {{mvar|A}} is polynomial but the expected running time of {{mvar|B}} is exponential.<ref name="bog06" />
To create a more robust definition of average-case efficiency, it makes sense to allow an algorithm {{mvar|A}} to run longer than polynomial time on some inputs but the fraction of inputs on which {{mvar|A}} requires larger and larger running time becomes smaller and smaller. This intuition is captured in the following formula for average polynomial running time, which balances the polynomial trade-off between running time and fraction of inputs:
:<math>
\Pr_{x \in_R D_n} \left[t_A(x) \geq t \right] \leq \frac{p(n)}{t^\epsilon}
</math>
for every {{math|''n'', ''t'' > 0}} and polynomial {{mvar|p}}, where {{math|''t''<sub>''A''</sub>(''x'')}} denotes the running time of algorithm {{mvar|A}} on input {{mvar|x}}, and {{mvar|ε}} is a positive constant value.<ref name="wangsurvey">{{cite book |last1=Wang |first1=Jie |url=https://www.cs.uml.edu/~wang/acc-forum/avgcomp.pdf |title=Complexity Theory: Retrospective II |date=1997 |publisher=Springer Science & Business Media |editor-last1=Hemaspaandra |editor-first1=Lane A. |volume=2 |pages=295–328 |chapter=Average-case computational complexity theory |editor-last2=Selman |editor-first2=Alan L.}}</ref> Alternatively, this can be written as
:<math>
E_{x \in_R D_n} \left[ \frac{t_{A}(x)^{\epsilon}}{n} \right] \leq C
</math>
for some constants {{mvar|C}} and {{mvar|ε}}, where {{math|''n'' {{=}} {{abs|''x''}}}}.<ref name="ab09">{{cite book |last1=Arora |first1=Sanjeev |title=Computational Complexity: A Modern Approach |last2=Barak |first2=Boaz |date=2009 |publisher=Cambridge University Press |___location=Cambridge; New York |chapter=18. Average case complexity: Levin’s theory}}</ref> In other words, an algorithm {{mvar|A}} has good average-case complexity if, after running for {{math|''t''<sub>''A''</sub>(''n'')}} steps, {{mvar|A}} can solve all but a {{math|{{sfrac|''n''<sup>''c''</sup>|(''t''<sub>''A''</sub>(''n''))<sup>''ε''</sup>}}}} fraction of inputs of length {{mvar|n}}, for some {{math|''ε'', ''c'' > 0}}.<ref name="bog06"/>
===Distributional problem===
The next step is to define the "average" input to a particular problem. This is achieved by associating the inputs of each problem with a particular probability distribution. That is, an "average-case" problem consists of a language {{mvar|L}} and an associated probability distribution {{mvar|D}} which forms the pair {{math|(''L'', ''D'')}}.<ref name="ab09"/> The two most common classes of distributions which are allowed are:
#Polynomial-time computable distributions ({{math|'''P'''}}-computable): these are distributions for which it is possible to compute the cumulative density of any given input {{mvar|x}}. More formally, given a probability distribution {{mvar|μ}} and a string {{math|''x'' ∈ {{mset|0, 1}}<sup>''n''</sup>}} it is possible to compute the value <math>\mu(x) = \sum\limits_{y \in \{0, 1\}^n : y \leq x} \Pr[y]</math> in polynomial time. This implies that {{math|Pr[''x'']}} is also computable in polynomial time.
#Polynomial-time samplable distributions ({{math|'''P'''}}-samplable): these are distributions from which it is possible to draw random samples in polynomial time.
These two formulations, while similar, are not equivalent. If a distribution is {{math|'''P'''}}-computable it is also {{math|'''P'''}}-samplable, but the converse is not true if [[P (complexity)|{{math|'''P'''}}]] ≠ {{math|'''P'''<sup>'''#P'''</sup>}}.<ref name="ab09"/>
===AvgP and distNP===
A distributional problem {{math|(''L'', ''D'')}} is in the complexity class {{math|'''AvgP'''}} if there is an efficient average-case algorithm for {{mvar|L}}, as defined above. The class {{math|'''AvgP'''}} is occasionally called {{math|'''distP'''}} in the literature.<ref name="ab09"/>
A distributional problem {{math|(''L'', ''D'')}} is in the complexity class {{math|'''distNP'''}} if {{mvar|L}} is in {{math|'''NP'''}} and {{mvar|D}} is {{math|'''P'''}}-computable. When {{mvar|L}} is in {{math|'''NP'''}} and {{mvar|D}} is {{math|'''P'''}}-samplable, {{math|(''L'', ''D'')}} belongs to {{math|'''sampNP'''}}.<ref name="ab09"/>
Together, {{math|'''AvgP'''}} and {{math|'''distNP'''}} define the average-case analogues of {{math|'''P'''}} and {{math|'''NP'''}}, respectively.<ref name="ab09"/>
==Reductions between distributional problems==
Let {{math|(''L'',''D'')}} and {{math|(''L′'', ''D′'')}} be two distributional problems. {{math|(''L'', ''D'')}} average-case reduces to {{math|(''L′'', ''D′'')}} (written {{math|(''L'', ''D'') ≤<sub>'''AvgP'''</sub> (''L′'', ''D′'')}}) if there is a function {{mvar|f}} that for every {{mvar|n}}, on input {{mvar|x}} can be computed in time polynomial in {{mvar|n}} and
#(Correctness) {{math|''x'' ∈ ''L''}} if and only if {{math|''f''(''x'') ∈ ''L′''}}
#(Domination) There are polynomials {{mvar|p}} and {{mvar|m}} such that, for every {{mvar|n}} and {{mvar|y}}, <math>\sum\limits_{x: f(x) = y} D_n(x) \leq p(n)D'_{m(n)}(y)</math>
The domination condition enforces the notion that if problem {{math|(''L'', ''D'')}} is hard on average, then {{math|(''L′'', ''D′'')}} is also hard on average. Intuitively, a reduction should provide a way to solve an instance {{mvar|x}} of problem {{mvar|L}} by computing {{math|''f''(''x'')}} and feeding the output to the algorithm which solves {{mvar|L'}}. Without the domination condition, this may not be possible since the algorithm which solves {{mvar|L}} in polynomial time on average may take super-polynomial time on a small number of inputs but {{mvar|f}} may map these inputs into a much larger set of {{mvar|D'}} so that algorithm {{mvar|A'}} no longer runs in polynomial time on average. The domination condition only allows such strings to occur polynomially as often in {{mvar|D'}}.<ref name="wangsurvey"/>
===DistNP-complete problems===
The average-case analogue to {{math|'''NP'''}}-completeness is {{math|'''distNP'''}}-completeness. A distributional problem {{math|(''L′'', ''D′'')}} is {{math|'''distNP'''}}-complete if {{math|(''L′'', ''D′'')}} is in {{math|'''distNP'''}} and for every {{math|(''L'', ''D'')}} in {{math|'''distNP'''}}, {{math|(''L'', ''D'')}} is average-case reducible to {{math|(''L′'', ''D′'')}}.<ref name="ab09" />
An example of a {{math|'''distNP'''}}-complete problem is the Bounded Halting Problem, {{math|({{mvar|BH}},''D'')}} (for any {{math|'''P'''}}-computable ''D'') defined as follows:
<math>BH = \{(M, x, 1^t) : M \text{ is a non-deterministic Turing machine that accepts } x \text{ in} \leq t \text{ steps}\}</math><ref name="ab09"/>
In his original paper, Levin showed an example of a distributional tiling problem that is average-case {{math|'''NP'''}}-complete.<ref name="levin86"/> A survey of known {{math|'''distNP'''}}-complete problems is available online.<ref name="wangsurvey"/>
One area of active research involves finding new {{math|'''distNP'''}}-complete problems. However, finding such problems can be complicated due to a result of Gurevich which shows that any distributional problem with a flat distribution cannot be {{math|'''distNP'''}}-complete unless [[EXP|{{math|'''EXP'''}}]] = [[NEXP|{{math|'''NEXP'''}}]].<ref name="gur87">{{Cite book |last=Gurevich |first=Yuri |chapter=Complete and incomplete randomized NP problems |date=October 1987 |title=28th Annual Symposium on Foundations of Computer Science (SFCS 1987) |pages=111–117 |doi=10.1109/SFCS.1987.14|isbn=0-8186-0807-2 }}</ref> (A flat distribution {{mvar|μ}} is one for which there exists an {{math|''ε'' > 0}} such that for any {{mvar|x}}, {{math|''μ''(''x'') ≤ 2<sup>−{{abs|''x''}}<sup>''ε''</sup></sup>}}.) A result by Livne shows that all natural {{math|'''NP'''}}-complete problems have {{math|'''DistNP'''}}-complete versions.<ref name="livne06">{{Cite journal |last=Livne |first=Noam |date=December 2010 |title=All Natural NP-Complete Problems Have Average-Case Complete Versions |url=http://link.springer.com/10.1007/s00037-010-0298-9 |journal=Computational Complexity |language=en |volume=19 |issue=4 |pages=477–499 |doi=10.1007/s00037-010-0298-9 |issn=1016-3328|url-access=subscription }}</ref> However, the goal of finding a natural distributional problem that is {{math|'''DistNP'''}}-complete has not yet been achieved.<ref name="gol97">{{Citation |last=Goldreich |first=Oded |title=Notes on Levin's Theory of Average-Case Complexity |date=2011 |work=Studies in Complexity and Cryptography. Miscellanea on the Interplay between Randomness and Computation |series=Lecture Notes in Computer Science |volume=6650 |pages=233–247 |editor-last=Goldreich |editor-first=Oded |url=http://link.springer.com/10.1007/978-3-642-22670-0_21 |access-date=2025-05-21 |place=Berlin, Heidelberg |publisher=Springer Berlin Heidelberg |doi=10.1007/978-3-642-22670-0_21 |isbn=978-3-642-22669-4|url-access=subscription }}</ref>
==Applications==
===Sorting algorithms===
As mentioned above, much early work relating to average-case complexity focused on problems for which polynomial-time algorithms already existed, such as sorting. For example, many sorting algorithms which utilize randomness, such as [[Quicksort]], have a worst-case running time of {{math|O(''n''<sup>2</sup>)}}, but an average-case running time of {{math|O(''n'' log(''n''))}}, where {{mvar|n}} is the length of the input to be sorted.<ref name="clrs">{{cite book | last1 = Cormen | first1 = Thomas H. | last2 = Leiserson | first2 = Charles E. | last3 = Rivest | first3 = Ronald L. | last4 = Stein | first4 = Clifford | title = Introduction to Algorithms | edition = 3rd | date = 2009 | orig-year = 1990 | publisher = MIT Press and McGraw-Hill | isbn=978-0-262-03384-8 |url=https://www.worldcat.org/title/311310321 |oclc=311310321}}</ref>
===Cryptography===
For most problems, average-case complexity analysis is undertaken to find efficient algorithms for a problem that is considered difficult in the worst-case. In cryptographic applications, however, the opposite is true: the worst-case complexity is irrelevant; we instead want a guarantee that the average-case complexity of every algorithm which "breaks" the cryptographic scheme is inefficient.<ref name="katz07">{{Cite book |last1=Katz |first1=Jonathan |title=Introduction to modern cryptography |last2=Lindell |first2=Yehuda |date=2021 |publisher=CRC Press |isbn=978-1-351-13303-6 |edition=3 |series=Chapman & Hall/CRC cryptography and network security series |___location=Boca Raton, FL}}</ref>{{pn|date=May 2025}}
Thus, all secure cryptographic schemes rely on the existence of [[one-way functions]].<ref name="bog06"/> Although the existence of one-way functions is still an open problem, many candidate one-way functions are based on hard problems such as [[integer factorization]] or computing the [[discrete log]]. Note that it is not desirable for the candidate function to be {{math|'''NP'''}}-complete since this would only guarantee that there is likely no efficient algorithm for solving the problem in the worst case; what we actually want is a guarantee that no efficient algorithm can solve the problem over random inputs (i.e. the average case). In fact, both the integer factorization and discrete log problems are in {{math|'''NP''' ∩ }}[[coNP|{{math|'''coNP'''}}]], and are therefore not believed to be {{math|'''NP'''}}-complete.<ref name="ab09"/> The fact that all of cryptography is predicated on the existence of average-case intractable problems in {{math|'''NP'''}} is one of the primary motivations for studying average-case complexity.
==Other results==
[[Yao's principle]], from a 1978 paper by [[Andrew Yao]], shows that for broad classes of computational problems, average-case complexity for a hard input distribution and a deterministic algorithm adapted to that distribution is the same thing as expected complexity for a fast randomized algorithm and its worst-case input.<ref>{{citation
| last = Yao | first = Andrew | author-link = Andrew Yao
| contribution = Probabilistic computations: Toward a unified measure of complexity
| doi = 10.1109/SFCS.1977.24
| pages = 222–227
| title = Proceedings of the 18th IEEE Symposium on Foundations of Computer Science (FOCS)
| year = 1977}}</ref>
In 1990, Impagliazzo and Levin showed that if there is an efficient average-case algorithm for a {{math|'''distNP'''}}-complete problem under the uniform distribution, then there is an average-case algorithm for every problem in {{math|'''NP'''}} under any polynomial-time samplable distribution.<ref name="imp90">R. Impagliazzo and L. Levin, "No Better Ways to Generate Hard NP Instances than Picking Uniformly at Random," in Proceedings of the 31st IEEE Sympo- sium on Foundations of Computer Science, pp. 812–821, 1990.</ref> Applying this theory to natural distributional problems remains an outstanding open question.<ref name="bog06"/>
In 1992, Ben-David et al. showed that if all languages in {{math|'''distNP'''}} have good-on-average decision algorithms, they also have good-on-average search algorithms. Further, they show that this conclusion holds under a weaker assumption: if every language in {{math|'''NP'''}} is easy on average for decision algorithms with respect to the uniform distribution, then it is also easy on average for search algorithms with respect to the uniform distribution.<ref name="bd92">{{Cite book |last1=Ben-David |first1=S. |last2=Chor |first2=B. |last3=Goldreich |first3=O. |chapter=On the theory of average case complexity |date=1989 |title=Proceedings of the twenty-first annual ACM symposium on Theory of computing - STOC '89 |chapter-url=http://portal.acm.org/citation.cfm?doid=73007.73027 |language=en |publisher=ACM Press |pages=204–216 |doi=10.1145/73007.73027 |isbn=978-0-89791-307-2}}</ref> Thus, cryptographic one-way functions can exist only if there are {{math|'''distNP'''}} problems over the uniform distribution that are hard on average for decision algorithms.
In 1993, Feigenbaum and Fortnow showed that it is not possible to prove, under non-adaptive random reductions, that the existence of a good-on-average algorithm for a {{math|'''distNP'''}}-complete problem under the uniform distribution implies the existence of worst-case efficient algorithms for all problems in {{math|'''NP'''}}.<ref name="ff93">{{Cite journal |last1=Feigenbaum |first1=Joan |last2=Fortnow |first2=Lance |date=October 1993 |title=Random-Self-Reducibility of Complete Sets |url=http://epubs.siam.org/doi/10.1137/0222061 |journal=SIAM Journal on Computing |language=en |volume=22 |issue=5 |pages=994–1005 |doi=10.1137/0222061 |issn=0097-5397|url-access=subscription }}</ref> In 2003, Bogdanov and Trevisan generalized this result to arbitrary non-adaptive reductions.<ref name="bog03">{{Cite journal |last1=Bogdanov |first1=Andrej |last2=Trevisan |first2=Luca |date=January 2006 |title=On Worst-Case to Average-Case Reductions for NP Problems |url=https://epubs.siam.org/doi/10.1137/S0097539705446974 |journal=SIAM Journal on Computing |language=en |volume=36 |issue=4 |pages=1119–1159 |doi=10.1137/S0097539705446974 |issn=0097-5397|url-access=subscription }}</ref> These results show that it is unlikely that any association can be made between average-case complexity and worst-case complexity via reductions.<ref name="bog06"/>
==See also==
* [[Probabilistic analysis of algorithms]]
*[[NP-complete problems]]
*[[Worst-case complexity]]
*[[Amortized analysis]]
*[[Best, worst and average case]]
==References==
{{Reflist|30em}}
==Further reading==
Pedagogical presentations:
* {{Cite book |last=Impagliazzo |first=R. |chapter=A personal view of average-case complexity |date=1995 |title=Proceedings of Structure in Complexity Theory. Tenth Annual IEEE Conference |publisher=IEEE Comput. Soc. Press |pages=134–147 |doi=10.1109/SCT.1995.514853 |isbn=978-0-8186-7052-7}}
* {{cite book |last1=Wang |first1=Jie |url=https://www.cs.uml.edu/~wang/acc-forum/avgcomp.pdf |title=Complexity Theory: Retrospective II |date=1997 |publisher=Springer Science & Business Media |editor-last1=Hemaspaandra |editor-first1=Lane A. |volume=2 |pages=295–328 |chapter=Average-case computational complexity theory |editor-last2=Selman |editor-first2=Alan L.}}
* {{Citation |last=Goldreich |first=Oded |title=Average Case Complexity, Revisited |date=2011 |work=Studies in Complexity and Cryptography. Miscellanea on the Interplay between Randomness and Computation |series=Lecture Notes in Computer Science |volume=6650 |pages=422–450 |editor-last=Goldreich |editor-first=Oded |url=https://www.wisdom.weizmann.ac.il/~oded/COL/aver.pdf |place=Berlin, Heidelberg |publisher=Springer Berlin Heidelberg |doi=10.1007/978-3-642-22670-0_29 |isbn=978-3-642-22669-4}}
* {{cite book |last1=Arora |first1=Sanjeev |title=Computational Complexity: A Modern Approach |last2=Barak |first2=Boaz |date=2009 |publisher=Cambridge University Press |___location=Cambridge; New York |chapter=18. Average case complexity: Levin’s theory}}
The literature of average case complexity includes the following work:
*{{citation
| last = Levin | first = Leonid | author-link = Leonid Levin
| doi = 10.1137/0215020
| issue = 1
| journal = SIAM Journal on Computing
| pages = 285–286
| title = Average case complete problems
| volume = 15
| year = 1986}}
*{{citation
| last = Franco | first = John
| doi = 10.1016/0020-0190(86)90051-7
| issue = 2
| journal = Information Processing Letters
| pages = 103–106
| title = On the probabilistic performance of algorithms for the satisfiability problem
| volume = 23
| year = 1986}}..
*{{citation
| last1 = Flajolet | first1 = Philippe | author1-link = Philippe Flajolet
| last2 = Vitter | first2 = J. S. | author2-link = Jeffrey Vitter
| date = August 1987
| publisher = Institut National de Recherche en Informatique et en Automatique, B.P. 105-78153 Le Chesnay Cedex France
| series = Tech. Report
| title = Average-case analysis of algorithms and data structures}}.
*{{citation
| last1 = Gurevich | first1 = Yuri | author1-link = Yuri Gurevich
| last2 = Shelah | first2 = Saharon | author2-link = Saharon Shelah
| doi = 10.1137/0216034
| issue = 3
| journal = SIAM Journal on Computing
| pages = 486–502
| title = Expected computation time for [[Hamiltonian path problem]]
| volume = 16
| year = 1987| citeseerx = 10.1.1.359.8982}}.
*{{citation
| last1 = Ben-David | first1 = Shai
| last2 = Chor | first2 = Benny | author2-link = Benny Chor
| last3 = Goldreich | first3 = Oded | author3-link = Oded Goldreich
| last4 = Luby | first4 = Michael | author4-link = Michael Luby
| contribution = On the theory of average case complexity
| pages = 204–216
| publisher = [[Association for Computing Machinery]]
| title = [[Symposium on Theory of Computing|Proc. 21st Annual Symposium on Theory of Computing]]
| year = 1989}}.
*{{citation
| last = Gurevich | first = Yuri | author-link = Yuri Gurevich
| doi = 10.1016/0022-0000(91)90007-R
| issue = 3
| journal = Journal of Computer and System Sciences
| pages = 346–398
| title = Average case completeness
| volume = 42
| year = 1991| hdl = 2027.42/29307
| hdl-access = free
}}. See also [http://research.microsoft.com/~gurevich/Opera/76.pdf 1989 draft].
*{{citation
| last1 = Selman | first1 = B.
| last2 = Mitchell | first2 = D.
| last3 = Levesque | first3 = H.
| contribution = Hard and easy distributions of SAT problems
| pages = 459–465
| title = Proc. 10th National Conference on Artificial Intelligence
| year = 1992}}.
*{{citation
| last1 = Schuler | first1 = Rainer
| last2 = Yamakami | first2 = Tomoyuki
| contribution = Structural average case complexity
| pages = 128–139
| publisher = Springer-Verlag
| series = Lecture Notes in Computer Science
| title = Proc. Foundations of Software Technology and Theoretical Computer Science
| volume = 652
| year = 1992}}.
*{{citation
| last1 = Reischuk | first1 = Rüdiger
| last2 = Schindelhauer | first2 = Christian
| contribution = Precise average case complexity
| pages = 650–661
| title = Proc. 10th Annual Symposium on Theoretical Aspects of Computer Science
| year = 1993}}.
*{{citation
| last1 = Venkatesan | first1 = R.
| last2 = Rajagopalan | first2 = S.
| contribution = Average case intractability of matrix and Diophantine problems
| pages = 632–642
| publisher = [[Association for Computing Machinery]]
| title = [[Symposium on Theory of Computing|Proc. 24th Annual Symposium on Theory of Computing]]
| year = 1992}}.
*{{citation
| last1 = Cox | first1 = Jim
| last2 = Ericson | first2 = Lars
| last3 = Mishra | first3 = Bud
| series = Technical Report TR1995-711 | publisher = New York University Computer Science Department
| title = The average case complexity of multilevel syllogistic
| url = http://www.cs.nyu.edu/csweb/Research/TechReports/TR1995-711/TR1995-711.pdf
| year = 1995}}.
[[Category:Randomized algorithms]]
[[Category:Analysis of algorithms]]
| |||